qpcpp.qm

<?xml version="1.0" encoding="UTF-8"?>
<model version="7.0.0" links="1" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:noNamespaceSchemaLocation="http://www.state-machine.com/qm/qm7.xsd">
 <documentation>QP/C++ Real-Time Embedded Framework (RTEF)
This model is used to generate the whole QP/C++ source code.

Copyright (c) 2005 Quantum Leaps, LLC. All rights reserved.

                   Q u a n t u m  L e a P s
                   ------------------------
                   Modern Embedded Software

SPDX-License-Identifier: GPL-3.0-or-later OR LicenseRef-QL-commercial

The QP/C++ software is dual-licensed under the terms of the open-source GNU
General Public License (GPL) or under the terms of one of the closed-
source Quantum Leaps commercial licenses.

Redistributions in source code must retain this top-level comment block.
Plagiarizing this software to sidestep the license obligations is illegal.

NOTE:
The GPL (see &lt;www.gnu.org/licenses/gpl-3.0&gt;) does NOT permit the
incorporation of the QP/C++ software into proprietary programs. Please
contact Quantum Leaps for commercial licensing options, which expressly
supersede the GPL and are designed explicitly for licensees interested
in using QP/C++ in closed-source proprietary applications.

Quantum Leaps contact information:
&lt;www.state-machine.com/licensing&gt;
&lt;info@state-machine.com&gt;</documentation>
 <!--${qpcpp}-->
 <framework name="qpcpp">
  <license name="LicenseRef-QL-dual">public
qpcpp
2025-12-31
Copyright (C) 2005 Quantum Leaps, LLC. All rights reserved.

                   Q u a n t u m  L e a P s
                   ------------------------
                   Modern Embedded Software

SPDX-License-Identifier: GPL-3.0-or-later OR LicenseRef-QL-commercial

The QP/C++ software is dual-licensed under the terms of the open-source
GNU General Public License (GPL) or under the terms of one of the closed-
source Quantum Leaps commercial licenses.

Redistributions in source code must retain this top-level comment block.
Plagiarizing this software to sidestep the license obligations is illegal.

NOTE:
The GPL does NOT permit the incorporation of this code into proprietary
programs. Please contact Quantum Leaps for commercial licensing options,
which expressly supersede the GPL and are designed explicitly for
closed-source distribution.

Quantum Leaps contact information:
&lt;www.state-machine.com/licensing&gt;
&lt;info@state-machine.com&gt;
#48B37CF39D4FD9DE279250B31FD388AFD0BE9B40</license>
 </framework>
 <!--${glob-types}-->
 <package name="glob-types" stereotype="0x00">
  <!--${glob-types::int_t}-->
  <attribute name="int_t" type="using" visibility="0x04" properties="0x00">
   <code> = int;</code>
  </attribute>
  <!--${glob-types::enum_t}-->
  <attribute name="enum_t" type="using" visibility="0x04" properties="0x00">
   <code> = int;</code>
  </attribute>
  <!--${glob-types::float32_t}-->
  <attribute name="float32_t" type="using" visibility="0x04" properties="0x00">
   <code> = float;</code>
  </attribute>
  <!--${glob-types::float64_t}-->
  <attribute name="float64_t" type="using" visibility="0x04" properties="0x00">
   <code> = double;</code>
  </attribute>
 </package>
 <!--${QEP}-->
 <package name="QEP" stereotype="0x05" namespace="QP::">
  <!--${QEP::versionStr[]}-->
  <attribute name="versionStr[]" type="constexpr char const" visibility="0x04" properties="0x01">
   <documentation>//! the current QP version number string in ROM, based on #QP_VERSION_STR</documentation>
   <code>{QP_VERSION_STR};</code>
  </attribute>
  <!--${QEP::QSignal}-->
  <attribute name="QSignal? (Q_SIGNAL_SIZE == 1U)" type="using" visibility="0x04" properties="0x00">
   <code>= std::uint8_t;</code>
  </attribute>
  <!--${QEP::QSignal}-->
  <attribute name="QSignal? (Q_SIGNAL_SIZE == 2U)" type="using" visibility="0x04" properties="0x00">
   <code>= std::uint16_t;</code>
  </attribute>
  <!--${QEP::QSignal}-->
  <attribute name="QSignal? (Q_SIGNAL_SIZE == 4U)" type="using" visibility="0x04" properties="0x00">
   <code>= std::uint32_t;</code>
  </attribute>
  <!--${QEP::QEvt}-->
  <class name="QEvt">
   <!--${QEP::QEvt::sig}-->
   <attribute name="sig" type="QSignal" visibility="0x00" properties="0x00"/>
   <!--${QEP::QEvt::evtTag_}-->
   <attribute name="evtTag_" type="std::uint8_t" visibility="0x00" properties="0x00"/>
   <!--${QEP::QEvt::refCtr_}-->
   <attribute name="refCtr_" type="std::uint8_t volatile" visibility="0x00" properties="0x00"/>
   <!--${QEP::QEvt::DynEvt}-->
   <attribute name="DynEvt" type="enum" visibility="0x04" properties="0x00">
    <code>: std::uint8_t { DYNAMIC };</code>
   </attribute>
   <!--${QEP::QEvt::QEvt}-->
   <operation name="QEvt" type="explicit constexpr" visibility="0x00" properties="0x02">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QEvt::QEvt::s}-->
    <parameter name="s" type="QSignal const"/>
    <code>  : sig(s),
    evtTag_(0x01U),
    refCtr_(0x0EU)</code>
   </operation>
   <!--${QEP::QEvt::QEvt}-->
   <operation name="QEvt" type="" visibility="0x00" properties="0x00">
    <specifiers>= delete</specifiers>
   </operation>
   <!--${QEP::QEvt::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x02">
    <specifiers>noexcept</specifiers>
    <code>// no event parameters to initialize</code>
   </operation>
   <!--${QEP::QEvt::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x02">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QEvt::init::dummy}-->
    <parameter name="dummy" type="DynEvt const"/>
    <code>static_cast&lt;void&gt;(dummy);
// no event parameters to initialize</code>
   </operation>
   <!--${QEP::QEvt::verify_}-->
   <operation name="verify_" type="bool" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>std::uint8_t rc = refCtr_;
return (rc &lt;= 2U*QF_MAX_ACTIVE)
       &amp;&amp; (((evtTag_ ^ rc) &amp; 0x0FU) == 0x0FU);</code>
   </operation>
   <!--${QEP::QEvt::getPoolNum_}-->
   <operation name="getPoolNum_" type="std::uint_fast8_t" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>return static_cast&lt;std::uint8_t&gt;(evtTag_ &gt;&gt; 4U);</code>
   </operation>
  </class>
  <!--${QEP::QState}-->
  <attribute name="QState" type="using" visibility="0x04" properties="0x00">
   <code>= std::uint_fast8_t;</code>
  </attribute>
  <!--${QEP::QStateHandler}-->
  <attribute name="QStateHandler" type="using" visibility="0x04" properties="0x00">
   <code>= QState (*)(void * const me, QEvt const * const e);</code>
  </attribute>
  <!--${QEP::QActionHandler}-->
  <attribute name="QActionHandler" type="using" visibility="0x04" properties="0x00">
   <code>= QState (*)(void * const me);</code>
  </attribute>
  <!--${QEP::QXThread}-->
  <attribute name="QXThread" type="class" visibility="0x04" properties="0x00">
   <documentation>// forward declaration</documentation>
  </attribute>
  <!--${QEP::QXThreadHandler}-->
  <attribute name="QXThreadHandler" type="using" visibility="0x04" properties="0x00">
   <code>= void (*)(QXThread * const me);</code>
  </attribute>
  <!--${QEP::QMState}-->
  <attribute name="QMState" type="struct" visibility="0x04" properties="0x00">
   <code>{
    QMState const *superstate;
    QStateHandler const stateHandler;
    QActionHandler const entryAction;
    QActionHandler const exitAction;
    QActionHandler const initAction;
};</code>
  </attribute>
  <!--${QEP::QMTranActTable}-->
  <attribute name="QMTranActTable" type="struct" visibility="0x04" properties="0x00">
   <code>{
    QMState const *target;
    QActionHandler const act[1];
};</code>
  </attribute>
  <!--${QEP::QAsmAttr}-->
  <attribute name="QAsmAttr" type="union" visibility="0x04" properties="0x00">
   <code>{
    QStateHandler   fun;
    QActionHandler  act;
    QXThreadHandler thr;
    QMState         const *obj;
    QMTranActTable  const *tatbl;
#ifndef Q_UNSAFE
    std::uintptr_t  uint;
#endif
    constexpr QAsmAttr() : fun(nullptr) {}
};</code>
  </attribute>
  <!--${QEP::Q_USER_SIG}-->
  <attribute name="Q_USER_SIG" type="constexpr enum_t " visibility="0x04" properties="0x00">
   <code>{4};</code>
  </attribute>
  <!--${QEP::QAsm}-->
  <class name="QAsm">
   <documentation>Abstract State Machine</documentation>
   <!--${QEP::QAsm::m_state}-->
   <attribute name="m_state" type="QAsmAttr" visibility="0x01" properties="0x00"/>
   <!--${QEP::QAsm::m_temp}-->
   <attribute name="m_temp" type="QAsmAttr" visibility="0x01" properties="0x00"/>
   <!--${QEP::QAsm::QStateRet}-->
   <attribute name="QStateRet" type="enum" visibility="0x04" properties="0x01">
    <documentation>//! All possible return values from state-handlers
//! @note
//! The order is important for algorithmic correctness.</documentation>
    <code> : QState {
        // unhandled and need to &quot;bubble up&quot;
        Q_RET_SUPER,     //!&lt; event passed to superstate to handle
        Q_RET_UNHANDLED, //!&lt; event unhandled due to a guard

        // handled and do not need to &quot;bubble up&quot;
        Q_RET_HANDLED,   //!&lt; event handled (internal transition)
        Q_RET_IGNORED,   //!&lt; event silently ignored (bubbled up to top)

        // entry/exit
        Q_RET_ENTRY,     //!&lt; state entry action executed
        Q_RET_EXIT,      //!&lt; state exit  action executed

        // no side effects
        Q_RET_NULL,      //!&lt; return value without any effect

        // transitions need to execute transition-action table in QP::QMsm
        Q_RET_TRAN,      //!&lt; regular transition
        Q_RET_TRAN_INIT, //!&lt; initial transition in a state

        // transitions that additionally clobber QHsm.m_state
        Q_RET_TRAN_HIST, //!&lt; transition to history of a given state
    };</code>
   </attribute>
   <!--${QEP::QAsm::ReservedSig}-->
   <attribute name="ReservedSig" type="enum" visibility="0x04" properties="0x01">
    <documentation>//! Reserved signals by the QP-framework.</documentation>
    <code> : QSignal {
        Q_EMPTY_SIG,     //!&lt; signal to execute the default case
        Q_ENTRY_SIG,     //!&lt; signal for entry actions
        Q_EXIT_SIG,      //!&lt; signal for exit actions
        Q_INIT_SIG       //!&lt; signal for nested initial transitions
    };</code>
   </attribute>
   <!--${QEP::QAsm::QAsm}-->
   <operation name="QAsm" type="explicit" visibility="0x01" properties="0x02">
    <specifiers>noexcept</specifiers>
    <code>  : m_state(),
    m_temp ()</code>
   </operation>
   <!--${QEP::QAsm::~QAsm}-->
   <operation name="~QAsm?def Q_XTOR" type="" visibility="0x00" properties="0x06">
    <specifiers>noexcept</specifiers>
    <code>// empty</code>
   </operation>
   <!--${QEP::QAsm::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x04">
    <specifiers>= 0</specifiers>
    <!--${QEP::QAsm::init::e}-->
    <parameter name="e" type="void const * const"/>
    <!--${QEP::QAsm::init::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
   </operation>
   <!--${QEP::QAsm::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x06">
    <!--${QEP::QAsm::init::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>this-&gt;init(nullptr, qsId);</code>
   </operation>
   <!--${QEP::QAsm::dispatch}-->
   <operation name="dispatch" type="void" visibility="0x00" properties="0x04">
    <specifiers>= 0</specifiers>
    <!--${QEP::QAsm::dispatch::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <!--${QEP::QAsm::dispatch::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
   </operation>
   <!--${QEP::QAsm::isIn}-->
   <operation name="isIn" type="bool" visibility="0x00" properties="0x06">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QAsm::isIn::state}-->
    <parameter name="state" type="QStateHandler const"/>
    <code>static_cast&lt;void&gt;(state);
return false;</code>
   </operation>
   <!--${QEP::QAsm::state}-->
   <operation name="state" type="QStateHandler" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>return m_state.fun;</code>
   </operation>
   <!--${QEP::QAsm::stateObj}-->
   <operation name="stateObj" type="QMState const *" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>return m_state.obj;</code>
   </operation>
   <!--${QEP::QAsm::getStateHandler}-->
   <operation name="getStateHandler?def Q_SPY" type="QStateHandler" visibility="0x00" properties="0x06">
    <specifiers>noexcept</specifiers>
    <code>return m_state.fun;</code>
   </operation>
   <!--${QEP::QAsm::top}-->
   <operation name="top" type="QState" visibility="0x00" properties="0x03">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QAsm::top::me}-->
    <parameter name="me" type="void * const"/>
    <!--${QEP::QAsm::top::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <code>static_cast&lt;void&gt;(me);
static_cast&lt;void&gt;(e);
return Q_RET_IGNORED; // the top state ignores all events</code>
   </operation>
   <!--${QEP::QAsm::tran}-->
   <operation name="tran" type="QState" visibility="0x01" properties="0x02">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QAsm::tran::target}-->
    <parameter name="target" type="QStateHandler const"/>
    <code>m_temp.fun = target;
return Q_RET_TRAN;</code>
   </operation>
   <!--${QEP::QAsm::tran_hist}-->
   <operation name="tran_hist" type="QState" visibility="0x01" properties="0x02">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QAsm::tran_hist::hist}-->
    <parameter name="hist" type="QStateHandler const"/>
    <code>m_temp.fun = hist;
return Q_RET_TRAN_HIST;</code>
   </operation>
   <!--${QEP::QAsm::super}-->
   <operation name="super" type="QState" visibility="0x01" properties="0x02">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QAsm::super::superstate}-->
    <parameter name="superstate" type="QStateHandler const"/>
    <code>m_temp.fun = superstate;
return Q_RET_SUPER;</code>
   </operation>
   <!--${QEP::QAsm::qm_tran}-->
   <operation name="qm_tran" type="QState" visibility="0x01" properties="0x02">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QAsm::qm_tran::tatbl}-->
    <parameter name="tatbl" type="void const * const"/>
    <code>m_temp.tatbl = static_cast&lt;QP::QMTranActTable const *&gt;(tatbl);
return Q_RET_TRAN;</code>
   </operation>
   <!--${QEP::QAsm::qm_tran_init}-->
   <operation name="qm_tran_init" type="QState" visibility="0x01" properties="0x02">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QAsm::qm_tran_init::tatbl}-->
    <parameter name="tatbl" type="void const * const"/>
    <code>m_temp.tatbl = static_cast&lt;QP::QMTranActTable const *&gt;(tatbl);
return Q_RET_TRAN_INIT;</code>
   </operation>
   <!--${QEP::QAsm::qm_tran_hist}-->
   <operation name="qm_tran_hist" type="QState" visibility="0x01" properties="0x02">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QAsm::qm_tran_hist::hist}-->
    <parameter name="hist" type="QMState const * const"/>
    <!--${QEP::QAsm::qm_tran_hist::tatbl}-->
    <parameter name="tatbl" type="void const * const"/>
    <code>m_state.obj  = hist;
m_temp.tatbl = static_cast&lt;QP::QMTranActTable const *&gt;(tatbl);
return Q_RET_TRAN_HIST;</code>
   </operation>
   <!--${QEP::QAsm::qm_entry}-->
   <operation name="qm_entry?def Q_SPY" type="QState" visibility="0x01" properties="0x02">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QAsm::qm_entry::s}-->
    <parameter name="s" type="QMState const * const"/>
    <code>m_temp.obj = s;
return Q_RET_ENTRY;</code>
   </operation>
   <!--${QEP::QAsm::qm_entry}-->
   <operation name="qm_entry?ndef Q_SPY" type="QState" visibility="0x01" properties="0x02">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QAsm::qm_entry::s}-->
    <parameter name="s" type="QMState const * const"/>
    <code>static_cast&lt;void&gt;(s); // unused parameter
return Q_RET_ENTRY;</code>
   </operation>
   <!--${QEP::QAsm::qm_exit}-->
   <operation name="qm_exit?def Q_SPY" type="QState" visibility="0x01" properties="0x02">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QAsm::qm_exit::s}-->
    <parameter name="s" type="QMState const * const"/>
    <code>m_temp.obj = s;
return Q_RET_EXIT;</code>
   </operation>
   <!--${QEP::QAsm::qm_exit}-->
   <operation name="qm_exit?ndef Q_SPY" type="QState" visibility="0x01" properties="0x02">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QAsm::qm_exit::s}-->
    <parameter name="s" type="QMState const * const"/>
    <code>static_cast&lt;void&gt;(s); // unused parameter
return Q_RET_EXIT;</code>
   </operation>
  </class>
  <!--${QEP::QHsm}-->
  <class name="QHsm" superclass="QEP::QAsm">
   <documentation>Human-generated State Machine</documentation>
   <!--${QEP::QHsm::QHsm}-->
   <operation name="QHsm" type="explicit" visibility="0x01" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QHsm::QHsm::initial}-->
    <parameter name="initial" type="QStateHandler const"/>
    <code>: QAsm()

m_state.fun = Q_STATE_CAST(&amp;top);
m_temp.fun  = initial;</code>
   </operation>
   <!--${QEP::QHsm::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x04">
    <specifiers>override</specifiers>
    <!--${QEP::QHsm::init::e}-->
    <parameter name="e" type="void const * const"/>
    <!--${QEP::QHsm::init::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>QF_CRIT_STAT

QState r;

// produce QS dictionary for QP::QHsm::top()
#ifdef Q_SPY
QS_CRIT_ENTRY();
QS_MEM_SYS();
if ((QS::priv_.flags &amp; 0x01U) == 0U) {
    QS::priv_.flags |= 0x01U;
    r = Q_RET_HANDLED;
}
else {
    r = Q_RET_IGNORED;
}
QS_MEM_APP();
QS_CRIT_EXIT();
if (r == Q_RET_HANDLED) {
    QS_FUN_DICTIONARY(&amp;QP::QHsm::top);
}
#else
Q_UNUSED_PAR(qsId);
#endif // def Q_SPY

QStateHandler t = m_state.fun;

QF_CRIT_ENTRY();
Q_REQUIRE_INCRIT(200, (m_temp.fun != nullptr)
                  &amp;&amp; (t == Q_STATE_CAST(&amp;top)));
QF_CRIT_EXIT();

// execute the top-most initial tran.
r = (*m_temp.fun)(this, Q_EVT_CAST(QEvt));

QF_CRIT_ENTRY();
// the top-most initial tran. must be taken
Q_ASSERT_INCRIT(210, r == Q_RET_TRAN);

QS_MEM_SYS();
QS_BEGIN_PRE(QS_QEP_STATE_INIT, qsId)
    QS_OBJ_PRE(this);         // this state machine object
    QS_FUN_PRE(t);            // the source state
    QS_FUN_PRE(m_temp.fun);   // the target of the initial tran.
QS_END_PRE()
QS_MEM_APP();

QF_CRIT_EXIT();

// drill down into the state hierarchy with initial transitions...
do {
    QStateHandler path[QHSM_MAX_NEST_DEPTH_]; // tran. entry path array
    std::int_fast8_t ip = 0; // tran. entry path index

    path[0] = m_temp.fun;
    static_cast&lt;void&gt;(QHSM_RESERVED_EVT_(m_temp.fun, Q_EMPTY_SIG));
    // note: ip is here the fixed upper loop bound
    while ((m_temp.fun != t) &amp;&amp; (ip &lt; (QHSM_MAX_NEST_DEPTH_ - 1))) {
        ++ip;
        path[ip] = m_temp.fun;
        static_cast&lt;void&gt;(QHSM_RESERVED_EVT_(m_temp.fun, Q_EMPTY_SIG));
    }
    QF_CRIT_ENTRY();
    // too many state nesting levels or &quot;malformed&quot; HSM
    Q_ENSURE_INCRIT(220, ip &lt; QHSM_MAX_NEST_DEPTH_);
    QF_CRIT_EXIT();

    m_temp.fun = path[0];

    // retrace the entry path in reverse (desired) order...
    // note: ip is the fixed upper loop bound
    do {
        // enter path[ip]
        if (QHSM_RESERVED_EVT_(path[ip], Q_ENTRY_SIG)
            == Q_RET_HANDLED)
        {
            QS_STATE_ENTRY_(path[ip], qsId);
        }
        --ip;
    } while (ip &gt;= 0);

    t = path[0]; // current state becomes the new source

    r = QHSM_RESERVED_EVT_(t, Q_INIT_SIG); // execute initial tran.

#ifdef Q_SPY
    if (r == Q_RET_TRAN) {
        QS_CRIT_ENTRY();
        QS_MEM_SYS();
        QS_BEGIN_PRE(QS_QEP_STATE_INIT, qsId)
            QS_OBJ_PRE(this);         // this state machine object
            QS_FUN_PRE(t);            // the source state
            QS_FUN_PRE(m_temp.fun);   // the target of the initial tran.
        QS_END_PRE()
        QS_MEM_APP();
        QS_CRIT_EXIT();
    }
#endif // Q_SPY
} while (r == Q_RET_TRAN);

QF_CRIT_ENTRY();

QS_MEM_SYS();
QS_BEGIN_PRE(QS_QEP_INIT_TRAN, qsId)
    QS_TIME_PRE();    // time stamp
    QS_OBJ_PRE(this); // this state machine object
    QS_FUN_PRE(t);    // the new active state
QS_END_PRE()
QS_MEM_APP();

QF_CRIT_EXIT();

m_state.fun = t;   // change the current active state
#ifndef Q_UNSAFE
m_temp.uint = ~m_state.uint;
#endif</code>
   </operation>
   <!--${QEP::QHsm::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x06">
    <specifiers>override</specifiers>
    <!--${QEP::QHsm::init::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>this-&gt;init(nullptr, qsId);</code>
   </operation>
   <!--${QEP::QHsm::dispatch}-->
   <operation name="dispatch" type="void" visibility="0x00" properties="0x04">
    <specifiers>override</specifiers>
    <!--${QEP::QHsm::dispatch::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <!--${QEP::QHsm::dispatch::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>#ifndef Q_SPY
Q_UNUSED_PAR(qsId);
#endif

QStateHandler s = m_state.fun;
QStateHandler t = s;
QF_CRIT_STAT

QF_CRIT_ENTRY();
Q_REQUIRE_INCRIT(300, (e != nullptr) &amp;&amp; (s != nullptr));
Q_INVARIANT_INCRIT(301,
    e-&gt;verify_()
    &amp;&amp; (m_state.uint == static_cast&lt;std::uintptr_t&gt;(~m_temp.uint)));

QS_MEM_SYS();
QS_BEGIN_PRE(QS_QEP_DISPATCH, qsId)
    QS_TIME_PRE();      // time stamp
    QS_SIG_PRE(e-&gt;sig); // the signal of the event
    QS_OBJ_PRE(this);   // this state machine object
    QS_FUN_PRE(s);      // the current state
QS_END_PRE()
QS_MEM_APP();

QF_CRIT_EXIT();

// process the event hierarchically...
QState r;
m_temp.fun = s;
std::int_fast8_t ip = QHSM_MAX_NEST_DEPTH_; // fixed upper loop bound
do {
    s = m_temp.fun;
    r = (*s)(this, e); // invoke state handler s

    if (r == Q_RET_UNHANDLED) { // unhandled due to a guard?

        QS_CRIT_ENTRY();
        QS_MEM_SYS();
        QS_BEGIN_PRE(QS_QEP_UNHANDLED, qsId)
            QS_SIG_PRE(e-&gt;sig); // the signal of the event
            QS_OBJ_PRE(this);   // this state machine object
            QS_FUN_PRE(s);      // the current state
        QS_END_PRE()
        QS_MEM_APP();
        QS_CRIT_EXIT();

        r = QHSM_RESERVED_EVT_(s, Q_EMPTY_SIG); // superstate of s
    }

    --ip;
} while ((r == Q_RET_SUPER) &amp;&amp; (ip &gt; 0));

QF_CRIT_ENTRY();
Q_ENSURE_INCRIT(310, ip &gt; 0);
QF_CRIT_EXIT();

if (r &gt;= Q_RET_TRAN) { // tran. (regular or history) taken?
#ifdef Q_SPY
    if (r == Q_RET_TRAN_HIST) { // tran. to history?
        QS_CRIT_ENTRY();
        QS_MEM_SYS();
        QS_BEGIN_PRE(QS_QEP_TRAN_HIST, qsId)
            QS_OBJ_PRE(this);         // this state machine object
            QS_FUN_PRE(s);            // tran. to history source
            QS_FUN_PRE(m_temp.fun);   // tran. to history target
        QS_END_PRE()
        QS_MEM_APP();
        QS_CRIT_EXIT();
    }
#endif // Q_SPY

    QStateHandler path[QHSM_MAX_NEST_DEPTH_];
    path[0] = m_temp.fun; // tran. target
    path[1] = t; // current state
    path[2] = s; // tran. source

    // exit current state to tran. source s...
    ip = QHSM_MAX_NEST_DEPTH_; // fixed upper loop bound
    for (; (t != s) &amp;&amp; (ip &gt; 0); t = m_temp.fun) {
        // exit from t
        if (QHSM_RESERVED_EVT_(t, Q_EXIT_SIG) == Q_RET_HANDLED) {
            QS_STATE_EXIT_(t, qsId);
            // find superstate of t
            static_cast&lt;void&gt;(QHSM_RESERVED_EVT_(t, Q_EMPTY_SIG));
        }
        --ip;
    }
    QF_CRIT_ENTRY();
    Q_ENSURE_INCRIT(320, ip &gt; 0);
    QF_CRIT_EXIT();

    ip = hsm_tran(&amp;path[0], qsId); // take the tran.

    // execute state entry actions in the desired order...
    // note: ip is the fixed upper loop bound
    for (; ip &gt;= 0; --ip) {
        // enter path[ip]
        if (QHSM_RESERVED_EVT_(path[ip], Q_ENTRY_SIG)
            == Q_RET_HANDLED)
        {
            QS_STATE_ENTRY_(path[ip], qsId);
        }
    }
    t = path[0];    // stick the target into register
    m_temp.fun = t; // update the next state

    // drill into the target hierarchy...
    while (QHSM_RESERVED_EVT_(t, Q_INIT_SIG) == Q_RET_TRAN) {

        QS_CRIT_ENTRY();
        QS_MEM_SYS();
        QS_BEGIN_PRE(QS_QEP_STATE_INIT, qsId)
            QS_OBJ_PRE(this);         // this state machine object
            QS_FUN_PRE(t);            // the source (pseudo)state
            QS_FUN_PRE(m_temp.fun);   // the target of the tran.
        QS_END_PRE()
        QS_MEM_APP();
        QS_CRIT_EXIT();

        ip = 0;
        path[0] = m_temp.fun;

        // find superstate
        static_cast&lt;void&gt;(QHSM_RESERVED_EVT_(m_temp.fun, Q_EMPTY_SIG));

        // note: ip is the fixed upper loop bound
        while ((m_temp.fun != t) &amp;&amp; (ip &lt; (QHSM_MAX_NEST_DEPTH_ - 1))) {
            ++ip;
            path[ip] = m_temp.fun;
            // find superstate
            static_cast&lt;void&gt;(
                QHSM_RESERVED_EVT_(m_temp.fun, Q_EMPTY_SIG));
        }
        QF_CRIT_ENTRY();
        // too many state nesting levels or &quot;malformed&quot; HSM
        Q_ENSURE_INCRIT(330, ip &lt; QHSM_MAX_NEST_DEPTH_);
        QF_CRIT_EXIT();

        m_temp.fun = path[0];

        // retrace the entry path in reverse (correct) order...
        // note: ip is the fixed upper loop bound
        do {
            // enter path[ip]
            if (QHSM_RESERVED_EVT_(path[ip], Q_ENTRY_SIG)
                == Q_RET_HANDLED)
            {
                QS_STATE_ENTRY_(path[ip], qsId);
            }
            --ip;
        } while (ip &gt;= 0);

        t = path[0]; // current state becomes the new source
    }

    QS_CRIT_ENTRY();
    QS_MEM_SYS();
    QS_BEGIN_PRE(QS_QEP_TRAN, qsId)
        QS_TIME_PRE();      // time stamp
        QS_SIG_PRE(e-&gt;sig); // the signal of the event
        QS_OBJ_PRE(this);   // this state machine object
        QS_FUN_PRE(s);      // the source of the tran.
        QS_FUN_PRE(t);      // the new active state
    QS_END_PRE()
    QS_MEM_APP();
    QS_CRIT_EXIT();
}

#ifdef Q_SPY
else if (r == Q_RET_HANDLED) {
    QS_CRIT_ENTRY();
    QS_MEM_SYS();
    QS_BEGIN_PRE(QS_QEP_INTERN_TRAN, qsId)
        QS_TIME_PRE();      // time stamp
        QS_SIG_PRE(e-&gt;sig); // the signal of the event
        QS_OBJ_PRE(this);   // this state machine object
        QS_FUN_PRE(s);      // the source state
    QS_END_PRE()
    QS_MEM_APP();
    QS_CRIT_EXIT();
}
else {
    QS_CRIT_ENTRY();
    QS_MEM_SYS();
    QS_BEGIN_PRE(QS_QEP_IGNORED, qsId)
        QS_TIME_PRE();      // time stamp
        QS_SIG_PRE(e-&gt;sig); // the signal of the event
        QS_OBJ_PRE(this);   // this state machine object
        QS_FUN_PRE(m_state.fun); // the current state
    QS_END_PRE()
    QS_MEM_APP();
    QS_CRIT_EXIT();
}
#endif // Q_SPY

m_state.fun = t; // change the current active state
#ifndef Q_UNSAFE
m_temp.uint = ~m_state.uint;
#endif</code>
   </operation>
   <!--${QEP::QHsm::isIn}-->
   <operation name="isIn" type="bool" visibility="0x00" properties="0x00">
    <specifiers>noexcept override</specifiers>
    <!--${QEP::QHsm::isIn::state}-->
    <parameter name="state" type="QStateHandler const"/>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
Q_INVARIANT_INCRIT(602,
    m_state.uint == static_cast&lt;std::uintptr_t&gt;(~m_temp.uint));
QF_CRIT_EXIT();

bool inState = false; // assume that this HSM is not in 'state'

// scan the state hierarchy bottom-up
QStateHandler s = m_state.fun;
std::int_fast8_t lbound = QHSM_MAX_NEST_DEPTH_ + 1; // fixed upper loop bound
QState r = Q_RET_SUPER;
for (; (r != Q_RET_IGNORED) &amp;&amp; (lbound &gt; 0); --lbound) {
    if (s == state) { // do the states match?
        inState = true;  // 'true' means that match found
        break; // break out of the for-loop
    }
    else {
        r = QHSM_RESERVED_EVT_(s, Q_EMPTY_SIG);
        s = m_temp.fun;
    }
}

QF_CRIT_ENTRY();
Q_ENSURE_INCRIT(690, lbound &gt; 0);
QF_CRIT_EXIT();

#ifndef Q_UNSAFE
m_temp.uint = ~m_state.uint;
#endif

return inState; // return the status</code>
   </operation>
   <!--${QEP::QHsm::childState}-->
   <operation name="childState" type="QStateHandler" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QHsm::childState::parent}-->
    <parameter name="parent" type="QStateHandler const"/>
    <code>QStateHandler child = m_state.fun; // start with current state
bool isFound = false; // start with the child not found

// establish stable state configuration
m_temp.fun = child;
QState r;
std::int_fast8_t lbound = QHSM_MAX_NEST_DEPTH_; // fixed upper loop bound
do {
    // is this the parent of the current child?
    if (m_temp.fun == parent) {
        isFound = true; // child is found
        r = Q_RET_IGNORED; // break out of the loop
    }
    else {
        child = m_temp.fun;
        r = QHSM_RESERVED_EVT_(m_temp.fun, Q_EMPTY_SIG);
    }
    --lbound;
} while ((r != Q_RET_IGNORED)  // the top state not reached
         &amp;&amp; (lbound &gt; 0));

#ifndef Q_UNSAFE
m_temp.uint = ~m_state.uint;
#else
Q_UNUSED_PAR(isFound);
#endif

QF_CRIT_STAT
QF_CRIT_ENTRY();
// NOTE: the following postcondition can only succeed when
// (lbound &gt; 0), so no extra check is necessary.
Q_ENSURE_INCRIT(890, isFound);
QF_CRIT_EXIT();

return child;</code>
   </operation>
   <!--${QEP::QHsm::getStateHandler}-->
   <operation name="getStateHandler?def Q_SPY" type="QStateHandler" visibility="0x00" properties="0x06">
    <specifiers>noexcept override</specifiers>
    <code>return m_state.fun;</code>
   </operation>
   <!--${QEP::QHsm::hsm_tran}-->
   <operation name="hsm_tran" type="std::int_fast8_t" visibility="0x02" properties="0x00">
    <!--${QEP::QHsm::hsm_tran::path}-->
    <parameter name="path" type="QStateHandler * const"/>
    <!--${QEP::QHsm::hsm_tran::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>#ifndef Q_SPY
Q_UNUSED_PAR(qsId);
#endif

std::int_fast8_t ip = -1; // tran. entry path index
QStateHandler t = path[0];
QStateHandler const s = path[2];
QF_CRIT_STAT

// (a) check source==target (tran. to self)...
if (s == t) {
    // exit source s
    if (QHSM_RESERVED_EVT_(s, Q_EXIT_SIG) == Q_RET_HANDLED) {
        QS_STATE_EXIT_(s, qsId);
    }
    ip = 0; // enter the target
}
else {
    // find superstate of target
    static_cast&lt;void&gt;(QHSM_RESERVED_EVT_(t, Q_EMPTY_SIG));

    t = m_temp.fun;

    // (b) check source==target-&gt;super...
    if (s == t) {
        ip = 0; // enter the target
    }
    else {
        // find superstate of src
        static_cast&lt;void&gt;(QHSM_RESERVED_EVT_(s, Q_EMPTY_SIG));

        // (c) check source-&gt;super==target-&gt;super...
        if (m_temp.fun == t) {
            // exit source s
            if (QHSM_RESERVED_EVT_(s, Q_EXIT_SIG) == Q_RET_HANDLED) {
                QS_STATE_EXIT_(s, qsId);
            }
            ip = 0; // enter the target
        }
        else {
            // (d) check source-&gt;super==target...
            if (m_temp.fun == path[0]) {
                // exit source s
                if (QHSM_RESERVED_EVT_(s, Q_EXIT_SIG) == Q_RET_HANDLED) {
                    QS_STATE_EXIT_(s, qsId);
                }
            }
            else {
                // (e) check rest of source==target-&gt;super-&gt;super..
                // and store the entry path along the way
                std::int_fast8_t iq = 0; // indicate that LCA was found
                ip = 1; // enter target and its superstate
                path[1] = t;      // save the superstate of target
                t = m_temp.fun;   // save source-&gt;super

                // find target-&gt;super-&gt;super...
                // note: ip is the fixed upper loop bound
                QState r = QHSM_RESERVED_EVT_(path[1], Q_EMPTY_SIG);
                while ((r == Q_RET_SUPER)
                       &amp;&amp; (ip &lt; (QHSM_MAX_NEST_DEPTH_ - 1)))
                {
                    ++ip;
                    path[ip] = m_temp.fun; // store the entry path
                    if (m_temp.fun == s) { // is it the source?
                        iq = 1; // indicate that the LCA found
                        --ip; // do not enter the source
                        r = Q_RET_HANDLED; // terminate the loop
                    }
                    else { // it is not the source, keep going up
                        r = QHSM_RESERVED_EVT_(m_temp.fun, Q_EMPTY_SIG);
                    }
                }
                QF_CRIT_ENTRY();
                // NOTE: The following postcondition succeeds only when
                // ip &lt; QHSM_MAX_NEST_DEPTH, so no additional check is necessary
                // too many state nesting levels or &quot;malformed&quot; HSM.
                Q_ENSURE_INCRIT(510, r != Q_RET_SUPER);
                QF_CRIT_EXIT();

                // the LCA not found yet?
                if (iq == 0) {
                    // exit source s
                    if (QHSM_RESERVED_EVT_(s, Q_EXIT_SIG)
                        == Q_RET_HANDLED)
                    {
                        QS_STATE_EXIT_(s, qsId);
                    }

                    // (f) check the rest of source-&gt;super
                    //                  == target-&gt;super-&gt;super...
                    iq = ip;
                    r = Q_RET_IGNORED; // indicate that the LCA NOT found
                    // note: iq is the fixed upper loop bound
                    do {
                        if (t == path[iq]) { // is this the LCA?
                            r = Q_RET_HANDLED; // indicate the LCA found
                            ip = iq - 1; // do not enter the LCA
                            iq = -1; // cause termination of the loop
                        }
                        else {
                            --iq; // try lower superstate of target
                        }
                    } while (iq &gt;= 0);

                    // the LCA not found yet?
                    if (r != Q_RET_HANDLED) {
                        // (g) check each source-&gt;super-&gt;...
                        // for each target-&gt;super...
                        r = Q_RET_IGNORED; // keep looping
                        std::int_fast8_t lbound = QHSM_MAX_NEST_DEPTH_;
                        do {
                            // exit from t
                            if (QHSM_RESERVED_EVT_(t, Q_EXIT_SIG)
                                == Q_RET_HANDLED)
                            {
                                QS_STATE_EXIT_(t, qsId);
                                // find superstate of t
                                static_cast&lt;void&gt;(
                                    QHSM_RESERVED_EVT_(t, Q_EMPTY_SIG));
                            }
                            t = m_temp.fun; // set to super of t
                            iq = ip;
                            do {
                                // is this the LCA?
                                if (t == path[iq]) {
                                    ip = iq - 1; // do not enter the LCA
                                    iq = -1;     // break out of inner loop
                                    r = Q_RET_HANDLED; // break outer loop
                                }
                                else {
                                    --iq;
                                }
                            } while (iq &gt;= 0);

                            --lbound;
                        } while ((r != Q_RET_HANDLED) &amp;&amp; (lbound &gt; 0));
                        QF_CRIT_ENTRY();
                        Q_ENSURE_INCRIT(530, lbound &gt; 0);
                        QF_CRIT_EXIT();
                    }
                }
            }
        }
    }
}
QF_CRIT_ENTRY();
Q_ENSURE_INCRIT(590, ip &lt; QHSM_MAX_NEST_DEPTH_);
QF_CRIT_EXIT();
return ip;</code>
   </operation>
  </class>
  <!--${QEP::QMsm}-->
  <class name="QMsm" superclass="QEP::QAsm">
   <documentation>Machine-generated State Machine</documentation>
   <!--${QEP::QMsm::QMsm}-->
   <operation name="QMsm" type="explicit" visibility="0x01" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QEP::QMsm::QMsm::initial}-->
    <parameter name="initial" type="QStateHandler const"/>
    <code>  : QAsm()

m_state.obj = &amp;l_msm_top_s; // the current state (top)
m_temp.fun  = initial;      // the initial tran. handler</code>
   </operation>
   <!--${QEP::QMsm::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x04">
    <specifiers>override</specifiers>
    <!--${QEP::QMsm::init::e}-->
    <parameter name="e" type="void const * const"/>
    <!--${QEP::QMsm::init::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>#ifndef Q_SPY
Q_UNUSED_PAR(qsId);
#endif

QF_CRIT_STAT
QF_CRIT_ENTRY();
Q_REQUIRE_INCRIT(200, (m_temp.fun != nullptr)
                  &amp;&amp; (m_state.obj == &amp;l_msm_top_s));
QF_CRIT_EXIT();

// execute the top-most initial tran.
QState r = (*m_temp.fun)(this, Q_EVT_CAST(QEvt));

QF_CRIT_ENTRY();
// the top-most initial tran. must be taken
Q_ASSERT_INCRIT(210, r == Q_RET_TRAN_INIT);

QS_MEM_SYS();
QS_BEGIN_PRE(QS_QEP_STATE_INIT, qsId)
    QS_OBJ_PRE(this);  // this state machine object
    QS_FUN_PRE(m_state.obj-&gt;stateHandler);          // source state
    QS_FUN_PRE(m_temp.tatbl-&gt;target-&gt;stateHandler); // target state
QS_END_PRE()
QS_MEM_APP();

QF_CRIT_EXIT();

// set state to the last tran. target
m_state.obj = m_temp.tatbl-&gt;target;

// drill down into the state hierarchy with initial transitions...
std::int_fast8_t lbound = QMSM_MAX_NEST_DEPTH_; // fixed upper loop bound
do {
    // execute the tran. table
    r = execTatbl_(m_temp.tatbl, qsId);
    --lbound;
} while ((r &gt;= Q_RET_TRAN_INIT) &amp;&amp; (lbound &gt; 0));

QF_CRIT_ENTRY();
Q_ENSURE_INCRIT(290, lbound &gt; 0);

QS_MEM_SYS();
QS_BEGIN_PRE(QS_QEP_INIT_TRAN, qsId)
    QS_TIME_PRE();    // time stamp
    QS_OBJ_PRE(this); // this state machine object
    QS_FUN_PRE(m_state.obj-&gt;stateHandler); // the new current state
QS_END_PRE()
QS_MEM_APP();

QF_CRIT_EXIT();

#ifndef Q_UNSAFE
m_temp.uint = ~m_state.uint;
#endif</code>
   </operation>
   <!--${QEP::QMsm::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x06">
    <specifiers>override</specifiers>
    <!--${QEP::QMsm::init::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>this-&gt;init(nullptr, qsId);</code>
   </operation>
   <!--${QEP::QMsm::dispatch}-->
   <operation name="dispatch" type="void" visibility="0x00" properties="0x04">
    <specifiers>override</specifiers>
    <!--${QEP::QMsm::dispatch::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <!--${QEP::QMsm::dispatch::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>#ifndef Q_SPY
Q_UNUSED_PAR(qsId);
#endif

QMState const *s = m_state.obj; // store the current state
QMState const *t = s;

QF_CRIT_STAT
QF_CRIT_ENTRY();
Q_REQUIRE_INCRIT(300, (e != nullptr) &amp;&amp; (s != nullptr));
Q_INVARIANT_INCRIT(301,
    e-&gt;verify_()
    &amp;&amp; (m_state.uint == static_cast&lt;std::uintptr_t&gt;(~m_temp.uint)));

QS_MEM_SYS();
QS_BEGIN_PRE(QS_QEP_DISPATCH, qsId)
    QS_TIME_PRE();               // time stamp
    QS_SIG_PRE(e-&gt;sig);          // the signal of the event
    QS_OBJ_PRE(this);            // this state machine object
    QS_FUN_PRE(s-&gt;stateHandler); // the current state handler
QS_END_PRE()
QS_MEM_APP();

QF_CRIT_EXIT();

// scan the state hierarchy up to the top state...
QState r;
std::int_fast8_t lbound = QMSM_MAX_NEST_DEPTH_; // fixed upper loop bound
do {
    r = (*t-&gt;stateHandler)(this, e); // call state handler function

    // event handled? (the most frequent case)
    if (r &gt;= Q_RET_HANDLED) {
        break; // done scanning the state hierarchy
    }
    // event unhandled and passed to the superstate?
    else if (r == Q_RET_SUPER) {
        t = t-&gt;superstate; // advance to the superstate
    }
    else { // event unhandled due to a guard
        QF_CRIT_ENTRY();
        // event must be unhandled due to a guard evaluating to 'false'
        Q_ASSERT_INCRIT(310, r == Q_RET_UNHANDLED);

        QS_MEM_SYS();
        QS_BEGIN_PRE(QS_QEP_UNHANDLED, qsId)
            QS_SIG_PRE(e-&gt;sig);  // the signal of the event
            QS_OBJ_PRE(this);    // this state machine object
            QS_FUN_PRE(t-&gt;stateHandler); // the current state
        QS_END_PRE()
        QS_MEM_APP();

        QF_CRIT_EXIT();

        t = t-&gt;superstate; // advance to the superstate
    }
    --lbound;
} while ((t != nullptr) &amp;&amp; (lbound &gt; 0));
QF_CRIT_ENTRY();
Q_ENSURE_INCRIT(320, lbound &gt; 0);
QF_CRIT_EXIT();

if (r &gt;= Q_RET_TRAN) { // any kind of tran. taken?
    QF_CRIT_ENTRY();
    // the tran. source state must not be nullptr
    Q_ASSERT_INCRIT(330, t != nullptr);
    QF_CRIT_EXIT();

#ifdef Q_SPY
    QMState const * const ts = t; // for saving tran. table
#endif // Q_SPY
    QMTranActTable const *tatbl;

    if (r == Q_RET_TRAN_HIST) { // was it tran. to history?
        QMState const * const hist = m_state.obj; // save history
        m_state.obj = s; // restore the original state

        QS_CRIT_ENTRY();
        QS_MEM_SYS();
        QS_BEGIN_PRE(QS_QEP_TRAN_HIST, qsId)
            QS_OBJ_PRE(this); // this state machine object
            QS_FUN_PRE(t-&gt;stateHandler);    // source state handler
            QS_FUN_PRE(hist-&gt;stateHandler); // target state handler
        QS_END_PRE()
        QS_MEM_APP();
        QS_CRIT_EXIT();

        // save the tran-action table before it gets clobbered
        tatbl = m_temp.tatbl;
        exitToTranSource_(s, t, qsId);
        static_cast&lt;void&gt;(execTatbl_(tatbl, qsId));
        r = enterHistory_(hist, qsId);
        s = m_state.obj;
        t = s; // set target to the current state
    }

    lbound = QMSM_MAX_NEST_DEPTH_; // fixed upper loop bound
    while ((r &gt;= Q_RET_TRAN) &amp;&amp; (lbound &gt; 0)) {
        // save the tran-action table before it gets clobbered
        tatbl = m_temp.tatbl;
        m_temp.obj = nullptr; // clear
        exitToTranSource_(s, t, qsId);
        r = execTatbl_(tatbl, qsId);
        s = m_state.obj;
        t = s; // set target to the current state
        --lbound;
    }

    QF_CRIT_ENTRY();
    Q_ENSURE_INCRIT(360, lbound &gt; 0);

    QS_MEM_SYS();
    QS_BEGIN_PRE(QS_QEP_TRAN, qsId)
        QS_TIME_PRE();                 // time stamp
        QS_SIG_PRE(e-&gt;sig);            // the signal of the event
        QS_OBJ_PRE(this);              // this state machine object
        QS_FUN_PRE(ts-&gt;stateHandler);  // the tran. source
        QS_FUN_PRE(s-&gt;stateHandler);   // the new active state
    QS_END_PRE()
    QS_MEM_APP();

    QF_CRIT_EXIT();
}

#ifdef Q_SPY
// was the event handled?
else if (r == Q_RET_HANDLED) {
    QF_CRIT_ENTRY();
    // internal tran. source can't be nullptr
    Q_ASSERT_INCRIT(380, t != nullptr);

    QS_MEM_SYS();
    QS_BEGIN_PRE(QS_QEP_INTERN_TRAN, qsId)
        QS_TIME_PRE();                 // time stamp
        QS_SIG_PRE(e-&gt;sig);            // the signal of the event
        QS_OBJ_PRE(this);              // this state machine object
        QS_FUN_PRE(t-&gt;stateHandler);   // the source state
    QS_END_PRE()
    QS_MEM_APP();

    QF_CRIT_EXIT();
}
// event bubbled to the 'top' state?
else if (t == nullptr) {
    QS_CRIT_ENTRY();
    QS_MEM_SYS();
    QS_BEGIN_PRE(QS_QEP_IGNORED, qsId)
        QS_TIME_PRE();                 // time stamp
        QS_SIG_PRE(e-&gt;sig);            // the signal of the event
        QS_OBJ_PRE(this);              // this state machine object
        QS_FUN_PRE(s-&gt;stateHandler);   // the current state
    QS_END_PRE()
    QS_MEM_APP();
    QS_CRIT_EXIT();
}
#endif // Q_SPY
else {
    // empty
}

#ifndef Q_UNSAFE
m_temp.uint = ~m_state.uint;
#endif</code>
   </operation>
   <!--${QEP::QMsm::getStateHandler}-->
   <operation name="getStateHandler?def Q_SPY" type="QStateHandler" visibility="0x00" properties="0x02">
    <specifiers>noexcept override</specifiers>
    <code>return m_state.obj-&gt;stateHandler;</code>
   </operation>
   <!--${QEP::QMsm::isIn}-->
   <operation name="isIn" type="bool" visibility="0x00" properties="0x00">
    <specifiers>noexcept override</specifiers>
    <!--${QEP::QMsm::isIn::state}-->
    <parameter name="state" type="QStateHandler const"/>
    <code>bool inState = false; // assume that this SM is not in 'state'

QMState const *s = m_state.obj;
std::int_fast8_t lbound = QMSM_MAX_NEST_DEPTH_; // fixed upper loop bound
for (; (s != nullptr) &amp;&amp; (lbound &gt; 0); --lbound) {
    if (s-&gt;stateHandler == state) { // match found?
        inState = true;
        break;
    }
    else {
        s = s-&gt;superstate; // advance to the superstate
    }
}

QF_CRIT_STAT
QF_CRIT_ENTRY();
Q_ENSURE_INCRIT(490, lbound &gt; 0);
QF_CRIT_EXIT();

return inState;</code>
   </operation>
   <!--${QEP::QMsm::childStateObj}-->
   <operation name="childStateObj" type="QMState const *" visibility="0x00" properties="0x00">
    <specifiers>const noexcept</specifiers>
    <!--${QEP::QMsm::childStateObj::parent}-->
    <parameter name="parent" type="QMState const * const"/>
    <code>QMState const *child = m_state.obj;
bool isFound = false; // start with the child not found
QMState const *s;

std::int_fast8_t lbound = QMSM_MAX_NEST_DEPTH_; // fixed upper loop bound
for (s = m_state.obj;
     (s != nullptr) &amp;&amp; (lbound &gt; 0);
     s = s-&gt;superstate)
{
    if (s == parent) {
        isFound = true; // child is found
        break;
    }
    else {
        child = s;
    }
    --lbound;
}
QF_CRIT_STAT
QF_CRIT_ENTRY();
Q_ENSURE_INCRIT(680, lbound &gt; 0);
QF_CRIT_EXIT();

if (!isFound) { // still not found?
    lbound = QMSM_MAX_NEST_DEPTH_; // fixed upper loop bound
    for (s = m_temp.obj;
         (s != nullptr) &amp;&amp; (lbound &gt; 0);
         s = s-&gt;superstate)
    {
        if (s == parent) {
            isFound = true; // child is found
            break;
        }
        else {
            child = s;
        }
        --lbound;
    }
}

QF_CRIT_ENTRY();
// NOTE: the following postcondition can only succeed when
// (lbound &gt; 0), so no extra check is necessary.
Q_ENSURE_INCRIT(690, isFound);
QF_CRIT_EXIT();

return child; // return the child</code>
   </operation>
   <!--${QEP::QMsm::execTatbl_}-->
   <operation name="execTatbl_" type="QState" visibility="0x02" properties="0x00">
    <!--${QEP::QMsm::execTatbl_::tatbl}-->
    <parameter name="tatbl" type="QMTranActTable const * const"/>
    <!--${QEP::QMsm::execTatbl_::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>#ifndef Q_SPY
Q_UNUSED_PAR(qsId);
#endif

QF_CRIT_STAT
QF_CRIT_ENTRY();
// precondition:
// - the tran-action table pointer must not be NULL
Q_REQUIRE_INCRIT(700, tatbl != nullptr);
QF_CRIT_EXIT();

QState r = Q_RET_NULL;
std::int_fast8_t lbound = QMSM_MAX_TRAN_LENGTH_; // fixed upper loop bound
QActionHandler const *a = &amp;tatbl-&gt;act[0];
for (; (*a != nullptr) &amp;&amp; (lbound &gt; 0); ++a) {
    r = (*(*a))(this); // call the action through the 'a' pointer
    --lbound;
#ifdef Q_SPY
    QS_CRIT_ENTRY();
    QS_MEM_SYS();
    if (r == Q_RET_ENTRY) {
        QS_BEGIN_PRE(QS_QEP_STATE_ENTRY, qsId)
            QS_OBJ_PRE(this); // this state machine object
            QS_FUN_PRE(m_temp.obj-&gt;stateHandler); // entered state
        QS_END_PRE()
    }
    else if (r == Q_RET_EXIT) {
        QS_BEGIN_PRE(QS_QEP_STATE_EXIT, qsId)
            QS_OBJ_PRE(this); // this state machine object
            QS_FUN_PRE(m_temp.obj-&gt;stateHandler); // exited state
        QS_END_PRE()
    }
    else if (r == Q_RET_TRAN_INIT) {
        QS_BEGIN_PRE(QS_QEP_STATE_INIT, qsId)
            QS_OBJ_PRE(this); // this state machine object
            QS_FUN_PRE(tatbl-&gt;target-&gt;stateHandler);        // source
            QS_FUN_PRE(m_temp.tatbl-&gt;target-&gt;stateHandler); // target
        QS_END_PRE()
    }
    else {
        // empty
    }
    QS_MEM_APP();
    QS_CRIT_EXIT();
#endif // Q_SPY
}
QF_CRIT_ENTRY();
// NOTE: the following postcondition can only succeed when
// (lbound &gt; 0), so no extra check is necessary.
Q_ENSURE_INCRIT(790, *a == nullptr);
QF_CRIT_EXIT();

m_state.obj = (r &gt;= Q_RET_TRAN)
    ? m_temp.tatbl-&gt;target
    : tatbl-&gt;target;
return r;</code>
   </operation>
   <!--${QEP::QMsm::exitToTranSource_}-->
   <operation name="exitToTranSource_" type="void" visibility="0x02" properties="0x00">
    <!--${QEP::QMsm::exitToTranSource~::cs}-->
    <parameter name="cs" type="QMState const * const"/>
    <!--${QEP::QMsm::exitToTranSource~::ts}-->
    <parameter name="ts" type="QMState const * const"/>
    <!--${QEP::QMsm::exitToTranSource~::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>#ifndef Q_SPY
Q_UNUSED_PAR(qsId);
#endif

QF_CRIT_STAT

// exit states from the current state to the tran. source state
QMState const *s = cs;
std::int_fast8_t lbound = QMSM_MAX_NEST_DEPTH_; // fixed upper loop bound
for (; (s != ts) &amp;&amp; (lbound &gt; 0); --lbound) {
    // exit action provided in state 's'?
    if (s-&gt;exitAction != nullptr) {
        // execute the exit action
        static_cast&lt;void&gt;((*s-&gt;exitAction)(this));

        QS_CRIT_ENTRY();
        QS_MEM_SYS();
        QS_BEGIN_PRE(QS_QEP_STATE_EXIT, qsId)
            QS_OBJ_PRE(this);            // this state machine object
            QS_FUN_PRE(s-&gt;stateHandler); // the exited state handler
        QS_END_PRE()
        QS_MEM_APP();
        QS_CRIT_EXIT();
    }

    s = s-&gt;superstate; // advance to the superstate
}
QF_CRIT_ENTRY();
Q_ENSURE_INCRIT(890, lbound &gt; 0);
QF_CRIT_EXIT();</code>
   </operation>
   <!--${QEP::QMsm::enterHistory_}-->
   <operation name="enterHistory_" type="QState" visibility="0x02" properties="0x00">
    <!--${QEP::QMsm::enterHistory_::hist}-->
    <parameter name="hist" type="QMState const * const"/>
    <!--${QEP::QMsm::enterHistory_::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>#ifndef Q_SPY
Q_UNUSED_PAR(qsId);
#endif

// record the entry path from current state to history
QMState const *epath[QMSM_MAX_ENTRY_DEPTH_];
QMState const *s = hist;
std::int_fast8_t i = 0; // tran. entry path index
while ((s != m_state.obj) &amp;&amp; (i &lt; (QMSM_MAX_ENTRY_DEPTH_ - 1))) {
    if (s-&gt;entryAction != nullptr) {
        epath[i] = s;
        ++i;
    }
    s = s-&gt;superstate;
}
QF_CRIT_STAT
QF_CRIT_ENTRY();
Q_ASSERT_INCRIT(910, s == m_state.obj);
QF_CRIT_EXIT();

// retrace the entry path in reverse (desired) order...
while (i &gt; 0) {
    --i;
    (*epath[i]-&gt;entryAction)(this); // run entry action in epath[i]

    QS_CRIT_ENTRY();
    QS_MEM_SYS();
    QS_BEGIN_PRE(QS_QEP_STATE_ENTRY, qsId)
        QS_OBJ_PRE(this);
        QS_FUN_PRE(epath[i]-&gt;stateHandler); // entered state handler
    QS_END_PRE()
    QS_MEM_APP();
    QS_CRIT_EXIT();
}

m_state.obj = hist; // set current state to the tran. target

// initial tran. present?
QState r;
if (hist-&gt;initAction != nullptr) {
    r = (*hist-&gt;initAction)(this); // execute the tran. action
    QS_CRIT_ENTRY();
    QS_MEM_SYS();
    QS_BEGIN_PRE(QS_QEP_STATE_INIT, qsId)
        QS_OBJ_PRE(this); // this state machine object
        QS_FUN_PRE(hist-&gt;stateHandler);                 // source
        QS_FUN_PRE(m_temp.tatbl-&gt;target-&gt;stateHandler); // target
    QS_END_PRE()
    QS_MEM_APP();
    QS_CRIT_EXIT();
}
else {
    r = Q_RET_NULL;
}

return r;</code>
   </operation>
   <!--${QEP::QMsm::topQMState}-->
   <operation name="topQMState" type="QMState const *" visibility="0x00" properties="0x00">
    <specifiers>const noexcept</specifiers>
    <code>return &amp;l_msm_top_s;</code>
   </operation>
  </class>
 </package>
 <!--${QEP-macros}-->
 <package name="QEP-macros" stereotype="0x02">
  <!--${QEP-macros::Q_STATE_DECL}-->
  <operation name="Q_STATE_DECL" type="" visibility="0x03" properties="0x00">
   <!--${QEP-macros::Q_STATE_DECL::state_}-->
   <parameter name="state_" type="&lt;state name&gt;"/>
   <code>\
    QP::QState state_ ## _h(QP::QEvt const * const e); \
    static QP::QState state_(void * const me, QP::QEvt const * const e)</code>
  </operation>
  <!--${QEP-macros::Q_STATE_DEF}-->
  <operation name="Q_STATE_DEF" type="" visibility="0x03" properties="0x00">
   <!--${QEP-macros::Q_STATE_DEF::subclass_}-->
   <parameter name="subclass_" type="&lt;QHsm subclass&gt;"/>
   <!--${QEP-macros::Q_STATE_DEF::state_}-->
   <parameter name="state_" type="&lt;state name&gt;"/>
   <code>\
    QP::QState subclass_::state_(void * const me, QP::QEvt const * const e) { \
        return static_cast&lt;subclass_ *&gt;(me)-&gt;state_ ## _h(e); } \
    QP::QState subclass_::state_ ## _h(QP::QEvt const * const e)</code>
  </operation>
  <!--${QEP-macros::Q_HANDLED}-->
  <operation name="Q_HANDLED" type="" visibility="0x03" properties="0x00">
   <code>(Q_RET_HANDLED)</code>
  </operation>
  <!--${QEP-macros::Q_UNHANDLED}-->
  <operation name="Q_UNHANDLED" type="" visibility="0x03" properties="0x00">
   <code>(Q_RET_UNHANDLED)</code>
  </operation>
  <!--${QEP-macros::Q_EVT_CAST}-->
  <operation name="Q_EVT_CAST" type="" visibility="0x03" properties="0x00">
   <!--${QEP-macros::Q_EVT_CAST::subclass_}-->
   <parameter name="subclass_" type="&lt;QEvt subclass&gt;"/>
   <code>(static_cast&lt;subclass_ const *&gt;(e))</code>
  </operation>
  <!--${QEP-macros::Q_STATE_CAST}-->
  <operation name="Q_STATE_CAST" type="" visibility="0x03" properties="0x00">
   <!--${QEP-macros::Q_STATE_CAST::handler_}-->
   <parameter name="handler_" type="&lt;state handler&gt;"/>
   <code>\
    (reinterpret_cast&lt;QP::QStateHandler&gt;(handler_))</code>
  </operation>
  <!--${QEP-macros::QM_STATE_DECL}-->
  <operation name="QM_STATE_DECL" type="" visibility="0x03" properties="0x00">
   <!--${QEP-macros::QM_STATE_DECL::state_}-->
   <parameter name="state_" type="&lt;state name&gt;"/>
   <code>\
    QP::QState state_ ## _h(QP::QEvt const * const e); \
    static QP::QState state_(void * const me, QP::QEvt const * const e); \
    static QP::QMState const state_ ## _s</code>
  </operation>
  <!--${QEP-macros::QM_ACTION_DECL}-->
  <operation name="QM_ACTION_DECL" type="" visibility="0x03" properties="0x00">
   <!--${QEP-macros::QM_ACTION_DECL::action_}-->
   <parameter name="action_" type="&lt;predefined&gt;"/>
   <code>\
    QP::QState action_ ## _h(); \
    static QP::QState action_(void * const me)</code>
  </operation>
  <!--${QEP-macros::QM_STATE_DEF}-->
  <operation name="QM_STATE_DEF" type="" visibility="0x03" properties="0x00">
   <!--${QEP-macros::QM_STATE_DEF::subclass_}-->
   <parameter name="subclass_" type="&lt;QMsm subclass&gt;"/>
   <!--${QEP-macros::QM_STATE_DEF::state_}-->
   <parameter name="state_" type="&lt;state name&gt;"/>
   <code>\
    QP::QState subclass_::state_(void * const me, QP::QEvt const * const e) {\
        return static_cast&lt;subclass_ *&gt;(me)-&gt;state_ ## _h(e); } \
    QP::QState subclass_::state_ ## _h(QP::QEvt const * const e)</code>
  </operation>
  <!--${QEP-macros::QM_ACTION_DEF}-->
  <operation name="QM_ACTION_DEF" type="" visibility="0x03" properties="0x00">
   <!--${QEP-macros::QM_ACTION_DEF::subclass_}-->
   <parameter name="subclass_" type="&lt;QMsm subclass&gt;"/>
   <!--${QEP-macros::QM_ACTION_DEF::action_}-->
   <parameter name="action_" type="&lt;predefined&gt;"/>
   <code> \
    QP::QState subclass_::action_(void * const me) { \
        return static_cast&lt;subclass_ *&gt;(me)-&gt;action_ ## _h(); } \
    QP::QState subclass_::action_ ## _h()</code>
  </operation>
  <!--${QEP-macros::QM_HANDLED}-->
  <operation name="QM_HANDLED" type="" visibility="0x03" properties="0x00">
   <code>(Q_RET_HANDLED)</code>
  </operation>
  <!--${QEP-macros::QM_UNHANDLED}-->
  <operation name="QM_UNHANDLED" type="" visibility="0x03" properties="0x00">
   <code>(Q_RET_HANDLED)</code>
  </operation>
  <!--${QEP-macros::QM_SUPER}-->
  <operation name="QM_SUPER" type="" visibility="0x03" properties="0x00">
   <code>(Q_RET_SUPER)</code>
  </operation>
  <!--${QEP-macros::QM_STATE_NULL}-->
  <attribute name="QM_STATE_NULL" type="&lt;action handler&gt;" visibility="0x03" properties="0x00">
   <code>(nullptr)</code>
  </attribute>
  <!--${QEP-macros::Q_ACTION_NULL}-->
  <attribute name="Q_ACTION_NULL" type="&lt;action handler&gt;" visibility="0x03" properties="0x00">
   <code>(nullptr)</code>
  </attribute>
  <!--${QEP-macros::Q_UNUSED_PAR}-->
  <operation name="Q_UNUSED_PAR" type="&lt;param type&gt;" visibility="0x03" properties="0x00">
   <!--${QEP-macros::Q_UNUSED_PAR::par_}-->
   <parameter name="par_" type="&lt;param type&gt;"/>
   <code>(static_cast&lt;void&gt;(par_))</code>
  </operation>
  <!--${QEP-macros::Q_DIM}-->
  <operation name="Q_DIM" type="unsigned" visibility="0x03" properties="0x00">
   <!--${QEP-macros::Q_DIM::array_}-->
   <parameter name="array_" type="1-dimensional array"/>
   <code>(sizeof(array_) / sizeof((array_)[0U]))</code>
  </operation>
  <!--${QEP-macros::Q_UINT2PTR_CAST}-->
  <operation name="Q_UINT2PTR_CAST" type="" visibility="0x03" properties="0x00">
   <!--${QEP-macros::Q_UINT2PTR_CAST::type_}-->
   <parameter name="type_" type=""/>
   <!--${QEP-macros::Q_UINT2PTR_CAST::uint_}-->
   <parameter name="uint_" type=""/>
   <code>(reinterpret_cast&lt;type_ *&gt;(uint_))</code>
  </operation>
  <!--${QEP-macros::INIT}-->
  <operation name="INIT?def Q_SPY" type="" visibility="0x03" properties="0x00">
   <!--${QEP-macros::INIT::qsId_}-->
   <parameter name="qsId_" type="std::uint8_fast8_t"/>
   <code>init((qsId_))</code>
  </operation>
  <!--${QEP-macros::INIT}-->
  <operation name="INIT?ndef Q_SPY" type="" visibility="0x03" properties="0x00">
   <!--${QEP-macros::INIT::dummy}-->
   <parameter name="dummy" type="std::uint8_fast8_t"/>
   <code>init(0U)</code>
  </operation>
  <!--${QEP-macros::DISPATCH}-->
  <operation name="DISPATCH?def Q_SPY" type="" visibility="0x03" properties="0x00">
   <!--${QEP-macros::DISPATCH::e_}-->
   <parameter name="e_" type="QP::QEvt const *"/>
   <!--${QEP-macros::DISPATCH::qsId_}-->
   <parameter name="qsId_" type="std::uint8_fast8_t"/>
   <code>dispatch((e_), (qsId_))</code>
  </operation>
  <!--${QEP-macros::DISPATCH}-->
  <operation name="DISPATCH?ndef Q_SPY" type="" visibility="0x03" properties="0x00">
   <!--${QEP-macros::DISPATCH::e_}-->
   <parameter name="e_" type="QP::QEvt const *"/>
   <!--${QEP-macros::DISPATCH::dummy}-->
   <parameter name="dummy" type="std::uint8_fast8_t"/>
   <code>dispatch((e_), 0U)</code>
  </operation>
 </package>
 <!--${QF}-->
 <package name="QF" stereotype="0x05" namespace="QP::">
  <!--${QF::types}-->
  <package name="types" stereotype="0x02">
   <!--${QF::types::QPrioSpec}-->
   <attribute name="QPrioSpec" type="using" visibility="0x04" properties="0x00">
    <code>= std::uint16_t;</code>
   </attribute>
   <!--${QF::types::QEvtPtr}-->
   <attribute name="QEvtPtr" type="using" visibility="0x04" properties="0x00">
    <code>= QEvt const *;</code>
   </attribute>
   <!--${QF::types::QTimeEvtCtr}-->
   <attribute name="QTimeEvtCtr? (QF_TIMEEVT_CTR_SIZE == 1U)" type="using" visibility="0x04" properties="0x00">
    <code>= std::uint8_t;</code>
   </attribute>
   <!--${QF::types::QTimeEvtCtr}-->
   <attribute name="QTimeEvtCtr? (QF_TIMEEVT_CTR_SIZE == 2U)" type="using" visibility="0x04" properties="0x00">
    <code>= std::uint16_t;</code>
   </attribute>
   <!--${QF::types::QTimeEvtCtr}-->
   <attribute name="QTimeEvtCtr? (QF_TIMEEVT_CTR_SIZE == 4U)" type="using" visibility="0x04" properties="0x00">
    <code>= std::uint32_t;</code>
   </attribute>
   <!--${QF::types::QPSetBits}-->
   <attribute name="QPSetBits? (QF_MAX_ACTIVE &lt;= 8U)" type="using" visibility="0x04" properties="0x00">
    <code>= std::uint8_t;</code>
   </attribute>
   <!--${QF::types::QPSetBits}-->
   <attribute name="QPSetBits? (8U &lt; QF_MAX_ACTIVE) &amp;&amp; (QF_MAX_ACTIVE &lt;= 16U)" type="using" visibility="0x04" properties="0x00">
    <code>= std::uint16_t;</code>
   </attribute>
   <!--${QF::types::QPSetBits}-->
   <attribute name="QPSetBits? (16 &lt; QF_MAX_ACTIVE)" type="using" visibility="0x04" properties="0x00">
    <code>= std::uint32_t;</code>
   </attribute>
   <!--${QF::types::QF_LOG2}-->
   <operation name="QF_LOG2?ndef QF_LOG2" type="std::uint_fast8_t" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::types::QF_LOG2::x}-->
    <parameter name="x" type="QP::QPSetBits"/>
    <code>static std::uint8_t const log2LUT[16] = {
    0U, 1U, 2U, 2U, 3U, 3U, 3U, 3U,
    4U, 4U, 4U, 4U, 4U, 4U, 4U, 4U
};
std::uint_fast8_t n = 0U;
QP::QPSetBits t;

#if (QF_MAX_ACTIVE &gt; 16U)
t = static_cast&lt;QP::QPSetBits&gt;(x &gt;&gt; 16U);
if (t != 0U) {
    n += 16U;
    x = t;
}
#endif
#if (QF_MAX_ACTIVE &gt; 8U)
t = (x &gt;&gt; 8U);
if (t != 0U) {
    n += 8U;
    x = t;
}
#endif
t = (x &gt;&gt; 4U);
if (t != 0U) {
    n += 4U;
    x = t;
}
return n + log2LUT[x];</code>
   </operation>
   <!--${QF::types::QPSet}-->
   <class name="QPSet">
    <!--${QF::types::QPSet::m_bits[((QF_MAX_ACTIVE + (8U*siz~}-->
    <attribute name="m_bits[((QF_MAX_ACTIVE + (8U*sizeof(QPSetBits))) - 1U)/(8U*sizeof(QPSetBits))]" type="QPSetBits" visibility="0x02" properties="0x00"/>
    <!--${QF::types::QPSet::setEmpty}-->
    <operation name="setEmpty" type="void" visibility="0x00" properties="0x02">
     <specifiers>noexcept</specifiers>
     <code>m_bits[0] = 0U;
#if (QF_MAX_ACTIVE &gt; 32)
m_bits[1] = 0U;
#endif</code>
    </operation>
    <!--${QF::types::QPSet::isEmpty}-->
    <operation name="isEmpty" type="bool" visibility="0x00" properties="0x02">
     <specifiers>const noexcept</specifiers>
     <code>#if (QF_MAX_ACTIVE &lt;= 32U)
return (m_bits[0] == 0U);
#else
return (m_bits[0] == 0U) ? (m_bits[1] == 0U) : false;
#endif</code>
    </operation>
    <!--${QF::types::QPSet::notEmpty}-->
    <operation name="notEmpty" type="bool" visibility="0x00" properties="0x02">
     <specifiers>const noexcept</specifiers>
     <code>#if (QF_MAX_ACTIVE &lt;= 32U)
return (m_bits[0] != 0U);
#else
return (m_bits[0] != 0U) ? true : (m_bits[1] != 0U);
#endif</code>
    </operation>
    <!--${QF::types::QPSet::hasElement}-->
    <operation name="hasElement" type="bool" visibility="0x00" properties="0x02">
     <specifiers>const noexcept</specifiers>
     <!--${QF::types::QPSet::hasElement::n}-->
     <parameter name="n" type="std::uint_fast8_t const"/>
     <code>#if (QF_MAX_ACTIVE &lt;= 32U)
return (m_bits[0] &amp; (static_cast&lt;QPSetBits&gt;(1U) &lt;&lt; (n - 1U))) != 0U;
#else
return (n &lt;= 32U)
    ? ((m_bits[0] &amp; (static_cast&lt;QPSetBits&gt;(1U) &lt;&lt; (n - 1U)))  != 0U)
    : ((m_bits[1] &amp; (static_cast&lt;QPSetBits&gt;(1U) &lt;&lt; (n - 33U))) != 0U);
#endif</code>
    </operation>
    <!--${QF::types::QPSet::insert}-->
    <operation name="insert" type="void" visibility="0x00" properties="0x02">
     <specifiers>noexcept</specifiers>
     <!--${QF::types::QPSet::insert::n}-->
     <parameter name="n" type="std::uint_fast8_t const"/>
     <code>#if (QF_MAX_ACTIVE &lt;= 32U)
m_bits[0] = (m_bits[0] | (static_cast&lt;QPSetBits&gt;(1U) &lt;&lt; (n - 1U)));
#else
if (n &lt;= 32U) {
    m_bits[0] = (m_bits[0] | (static_cast&lt;QPSetBits&gt;(1U) &lt;&lt; (n - 1U)));
}
else {
    m_bits[1] = (m_bits[1] | (static_cast&lt;QPSetBits&gt;(1U) &lt;&lt; (n - 33U)));
}
#endif</code>
    </operation>
    <!--${QF::types::QPSet::remove}-->
    <operation name="remove" type="void" visibility="0x00" properties="0x02">
     <specifiers>noexcept</specifiers>
     <!--${QF::types::QPSet::remove::n}-->
     <parameter name="n" type="std::uint_fast8_t const"/>
     <code>#if (QF_MAX_ACTIVE &lt;= 32U)
m_bits[0] = (m_bits[0] &amp; static_cast&lt;QPSetBits&gt;(~(1U &lt;&lt; (n - 1U))));
#else
if (n &lt;= 32U) {
    (m_bits[0] = (m_bits[0] &amp; ~(static_cast&lt;QPSetBits&gt;(1U) &lt;&lt; (n - 1U))));
}
else {
    (m_bits[1] = (m_bits[1] &amp; ~(static_cast&lt;QPSetBits&gt;(1U) &lt;&lt; (n - 33U))));
}
#endif</code>
    </operation>
    <!--${QF::types::QPSet::findMax}-->
    <operation name="findMax" type="std::uint_fast8_t" visibility="0x00" properties="0x02">
     <specifiers>const noexcept</specifiers>
     <code>#if (QF_MAX_ACTIVE &lt;= 32U)
return QF_LOG2(m_bits[0]);
#else
return (m_bits[1] != 0U)
    ? (QF_LOG2(m_bits[1]) + 32U)
    : (QF_LOG2(m_bits[0]));
#endif</code>
    </operation>
    <!--${QF::types::QPSet::update_}-->
    <operation name="update_?ndef Q_UNSAFE" type="void" visibility="0x00" properties="0x02">
     <specifiers>const noexcept</specifiers>
     <!--${QF::types::QPSet::update_::dis}-->
     <parameter name="dis" type="QPSet * const"/>
     <code>dis-&gt;m_bits[0] = ~m_bits[0];
#if (QF_MAX_ACTIVE &gt; 32U)
dis-&gt;m_bits[1] = ~m_bits[1];
#endif</code>
    </operation>
    <!--${QF::types::QPSet::verify_}-->
    <operation name="verify_?ndef Q_UNSAFE" type="bool" visibility="0x00" properties="0x02">
     <specifiers>const noexcept</specifiers>
     <!--${QF::types::QPSet::verify_::dis}-->
     <parameter name="dis" type="QPSet const * const"/>
     <code>#if (QF_MAX_ACTIVE &lt;= 32U)
return m_bits[0] == static_cast&lt;QPSetBits&gt;(~dis-&gt;m_bits[0]);
#else
return (m_bits[0] == static_cast&lt;QPSetBits&gt;(~dis-&gt;m_bits[0]))
       &amp;&amp; (m_bits[1] == static_cast&lt;QPSetBits&gt;(~dis-&gt;m_bits[1]));
#endif</code>
    </operation>
   </class>
   <!--${QF::types::QSubscrList}-->
   <class name="QSubscrList">
    <!--${QF::types::QSubscrList::m_set}-->
    <attribute name="m_set" type="QPSet" visibility="0x02" properties="0x00"/>
    <!--${QF::types::QSubscrList::m_set_dis}-->
    <attribute name="m_set_dis?ndef Q_UNSAFE" type="QPSet" visibility="0x02" properties="0x00"/>
    <!--${QF::types::QSubscrList::QActive}-->
    <attribute name="QActive" type="friend class" visibility="0x02" properties="0x00">
     <documentation>// friends...</documentation>
    </attribute>
   </class>
   <!--${QF::types::QPtrDis}-->
   <class name="QPtrDis">
    <!--${QF::types::QPtrDis::m_ptr_dis}-->
    <attribute name="m_ptr_dis" type="std::uintptr_t" visibility="0x02" properties="0x00"/>
    <!--${QF::types::QPtrDis::QTimeEvt}-->
    <attribute name="QTimeEvt" type="friend class" visibility="0x02" properties="0x00">
     <documentation>// friends...</documentation>
    </attribute>
    <!--${QF::types::QPtrDis::QXThread}-->
    <attribute name="QXThread" type="friend class" visibility="0x02" properties="0x00">
     <documentation>// friends...</documentation>
    </attribute>
    <!--${QF::types::QPtrDis::QPtrDis}-->
    <operation name="QPtrDis" type="" visibility="0x00" properties="0x00">
     <specifiers>noexcept</specifiers>
     <!--${QF::types::QPtrDis::QPtrDis::ptr = nullptr}-->
     <parameter name="ptr = nullptr" type="void const * const"/>
     <code>  : m_ptr_dis(static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(ptr)))</code>
    </operation>
   </class>
   <!--${QF::types::QEQueue}-->
   <attribute name="QEQueue" type="class" visibility="0x04" properties="0x00"/>
  </package>
  <!--${QF::QActive}-->
  <class name="QActive" superclass="QEP::QAsm">
   <!--${QF::QActive::m_prio}-->
   <attribute name="m_prio" type="std::uint8_t" visibility="0x01" properties="0x00"/>
   <!--${QF::QActive::m_pthre}-->
   <attribute name="m_pthre" type="std::uint8_t" visibility="0x01" properties="0x00"/>
   <!--${QF::QActive::m_thread}-->
   <attribute name="m_thread?def QACTIVE_THREAD_TYPE" type="QACTIVE_THREAD_TYPE" visibility="0x01" properties="0x00"/>
   <!--${QF::QActive::m_osObject}-->
   <attribute name="m_osObject?def QACTIVE_OS_OBJ_TYPE" type="QACTIVE_OS_OBJ_TYPE" visibility="0x01" properties="0x00"/>
   <!--${QF::QActive::m_eQueue}-->
   <attribute name="m_eQueue?def QACTIVE_EQUEUE_TYPE" type="QACTIVE_EQUEUE_TYPE" visibility="0x01" properties="0x00"/>
   <!--${QF::QActive::m_prio_dis}-->
   <attribute name="m_prio_dis?ndef Q_UNSAFE" type="std::uint8_t" visibility="0x00" properties="0x00"/>
   <!--${QF::QActive::m_pthre_dis}-->
   <attribute name="m_pthre_dis?ndef Q_UNSAFE" type="std::uint8_t" visibility="0x00" properties="0x00"/>
   <!--${QF::QActive::registry_[QF_MAX_ACTIVE + 1U]}-->
   <attribute name="registry_[QF_MAX_ACTIVE + 1U]" type="QActive *" visibility="0x00" properties="0x01"/>
   <!--${QF::QActive::subscrList_}-->
   <attribute name="subscrList_" type="QSubscrList *" visibility="0x00" properties="0x01"/>
   <!--${QF::QActive::maxPubSignal_}-->
   <attribute name="maxPubSignal_" type="enum_t" visibility="0x00" properties="0x01"/>
   <!--${QF::QActive::QTimeEvt}-->
   <attribute name="QTimeEvt" type="friend class" visibility="0x00" properties="0x00">
    <documentation>// friends...</documentation>
   </attribute>
   <!--${QF::QActive::QTicker}-->
   <attribute name="QTicker" type="friend class" visibility="0x00" properties="0x00"/>
   <!--${QF::QActive::QXThread}-->
   <attribute name="QXThread" type="friend class" visibility="0x00" properties="0x00"/>
   <!--${QF::QActive::QXMutex}-->
   <attribute name="QXMutex" type="friend class" visibility="0x00" properties="0x00"/>
   <!--${QF::QActive::QXSemaphore}-->
   <attribute name="QXSemaphore" type="friend class" visibility="0x00" properties="0x00"/>
   <!--${QF::QActive::QActiveDummy}-->
   <attribute name="QActiveDummy" type="friend class" visibility="0x00" properties="0x00"/>
   <!--${QF::QActive::GuiQActive}-->
   <attribute name="GuiQActive" type="friend class" visibility="0x00" properties="0x00"/>
   <!--${QF::QActive::GuiQMActive}-->
   <attribute name="GuiQMActive" type="friend class" visibility="0x00" properties="0x00"/>
   <!--${QF::QActive::schedLock()}-->
   <attribute name="schedLock()" type="friend void" visibility="0x00" properties="0x00"/>
   <!--${QF::QActive::QActive}-->
   <operation name="QActive" type="explicit" visibility="0x01" properties="0x02">
    <specifiers>noexcept</specifiers>
    <!--${QF::QActive::QActive::initial}-->
    <parameter name="initial" type="QStateHandler const"/>
    <code>  : QAsm(),
    m_prio(0U),
    m_pthre(0U)

m_state.fun = Q_STATE_CAST(&amp;top);
m_temp.fun  = initial;

#ifndef Q_UNSAFE
m_prio_dis  = static_cast&lt;std::uint8_t&gt;(~m_prio);
m_pthre_dis = static_cast&lt;std::uint8_t&gt;(~m_pthre);
#endif</code>
   </operation>
   <!--${QF::QActive::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x02">
    <specifiers>override</specifiers>
    <!--${QF::QActive::init::e}-->
    <parameter name="e" type="void const * const"/>
    <!--${QF::QActive::init::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>reinterpret_cast&lt;QHsm *&gt;(this)-&gt;QHsm::init(e, qsId);</code>
   </operation>
   <!--${QF::QActive::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x06">
    <specifiers>override</specifiers>
    <!--${QF::QActive::init::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>this-&gt;init(nullptr, qsId);</code>
   </operation>
   <!--${QF::QActive::dispatch}-->
   <operation name="dispatch" type="void" visibility="0x00" properties="0x02">
    <specifiers>override</specifiers>
    <!--${QF::QActive::dispatch::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <!--${QF::QActive::dispatch::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>reinterpret_cast&lt;QHsm *&gt;(this)-&gt;QHsm::dispatch(e, qsId);</code>
   </operation>
   <!--${QF::QActive::isIn}-->
   <operation name="isIn" type="bool" visibility="0x00" properties="0x02">
    <specifiers>noexcept override</specifiers>
    <!--${QF::QActive::isIn::state}-->
    <parameter name="state" type="QStateHandler const"/>
    <code>return reinterpret_cast&lt;QHsm *&gt;(this)-&gt;QHsm::isIn(state);</code>
   </operation>
   <!--${QF::QActive::childState}-->
   <operation name="childState" type="QStateHandler" visibility="0x00" properties="0x02">
    <specifiers>noexcept</specifiers>
    <!--${QF::QActive::childState::parent}-->
    <parameter name="parent" type="QStateHandler const"/>
    <code>return reinterpret_cast&lt;QHsm *&gt;(this)-&gt;QHsm::childState(parent);</code>
   </operation>
   <!--${QF::QActive::setAttr}-->
   <operation name="setAttr" type="void" visibility="0x00" properties="0x00">
    <!--${QF::QActive::setAttr::attr1}-->
    <parameter name="attr1" type="std::uint32_t"/>
    <!--${QF::QActive::setAttr::attr2 = nullptr}-->
    <parameter name="attr2 = nullptr" type="void const *"/>
   </operation>
   <!--${QF::QActive::start}-->
   <operation name="start" type="void" visibility="0x00" properties="0x00">
    <!--${QF::QActive::start::prioSpec}-->
    <parameter name="prioSpec" type="QPrioSpec const"/>
    <!--${QF::QActive::start::qSto}-->
    <parameter name="qSto" type="QEvtPtr * const"/>
    <!--${QF::QActive::start::qLen}-->
    <parameter name="qLen" type="std::uint_fast16_t const"/>
    <!--${QF::QActive::start::stkSto}-->
    <parameter name="stkSto" type="void * const"/>
    <!--${QF::QActive::start::stkSize}-->
    <parameter name="stkSize" type="std::uint_fast16_t const"/>
    <!--${QF::QActive::start::par}-->
    <parameter name="par" type="void const * const"/>
   </operation>
   <!--${QF::QActive::start}-->
   <operation name="start" type="void" visibility="0x00" properties="0x02">
    <!--${QF::QActive::start::prioSpec}-->
    <parameter name="prioSpec" type="QPrioSpec const"/>
    <!--${QF::QActive::start::qSto}-->
    <parameter name="qSto" type="QEvtPtr * const"/>
    <!--${QF::QActive::start::qLen}-->
    <parameter name="qLen" type="std::uint_fast16_t const"/>
    <!--${QF::QActive::start::stkSto}-->
    <parameter name="stkSto" type="void * const"/>
    <!--${QF::QActive::start::stkSize}-->
    <parameter name="stkSize" type="std::uint_fast16_t const"/>
    <code>this-&gt;start(prioSpec, qSto, qLen, stkSto, stkSize, nullptr);</code>
   </operation>
   <!--${QF::QActive::stop}-->
   <operation name="stop?def QACTIVE_CAN_STOP" type="void" visibility="0x00" properties="0x00"/>
   <!--${QF::QActive::register_}-->
   <operation name="register_" type="void" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

if (m_pthre == 0U) { // preemption-threshold not defined?
    m_pthre = m_prio; // apply the default
}

#ifndef Q_UNSAFE

Q_REQUIRE_INCRIT(100, (0U &lt; m_prio) &amp;&amp; (m_prio &lt;= QF_MAX_ACTIVE)
                  &amp;&amp; (registry_[m_prio] == nullptr)
                  &amp;&amp; (m_prio &lt;= m_pthre));

std::uint8_t prev_thre = m_pthre;
std::uint8_t next_thre = m_pthre;

std::uint_fast8_t p;
for (p = static_cast&lt;std::uint_fast8_t&gt;(m_prio) - 1U; p &gt; 0U; --p) {
    if (registry_[p] != nullptr) {
        prev_thre = registry_[p]-&gt;m_pthre;
        break;
    }
}
for (p = static_cast&lt;std::uint_fast8_t&gt;(m_prio) + 1U;
     p &lt;= QF_MAX_ACTIVE; ++p)
{
    if (registry_[p] != nullptr) {
        next_thre = registry_[p]-&gt;m_pthre;
        break;
    }
}

Q_ASSERT_INCRIT(190, (prev_thre &lt;= m_pthre)
                      &amp;&amp; (m_pthre &lt;= next_thre));

m_prio_dis  = static_cast&lt;std::uint8_t&gt;(~m_prio);
m_pthre_dis = static_cast&lt;std::uint8_t&gt;(~m_pthre);

#endif // Q_UNSAFE

// register the AO at the QF-prio.
registry_[m_prio] = this;

QF_MEM_APP();
QF_CRIT_EXIT();</code>
   </operation>
   <!--${QF::QActive::unregister_}-->
   <operation name="unregister_" type="void" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <code>std::uint_fast8_t const p = static_cast&lt;std::uint_fast8_t&gt;(m_prio);

QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_REQUIRE_INCRIT(200, (0U &lt; p) &amp;&amp; (p &lt;= QF_MAX_ACTIVE)
                  &amp;&amp; (registry_[p] == this));
registry_[p] = nullptr; // free-up the priority level
m_state.fun = nullptr; // invalidate the state

QF_MEM_APP();
QF_CRIT_EXIT();</code>
   </operation>
   <!--${QF::QActive::post_}-->
   <operation name="post_" type="bool" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QActive::post_::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <!--${QF::QActive::post_::margin}-->
    <parameter name="margin" type="std::uint_fast16_t const"/>
    <!--${QF::QActive::post_::sender}-->
    <parameter name="sender" type="void const * const"/>
    <code>#ifndef Q_SPY
Q_UNUSED_PAR(sender);
#endif

#ifdef Q_UTEST // test?
#if (Q_UTEST != 0) // testing QP-stub?
if (m_temp.fun == Q_STATE_CAST(0)) { // QActiveDummy?
    return static_cast&lt;QActiveDummy *&gt;(this)-&gt;fakePost(e, margin, sender);
}
#endif // (Q_UTEST != 0)
#endif // def Q_UTEST

QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_REQUIRE_INCRIT(200, e != nullptr);

QEQueueCtr tmp = m_eQueue.m_nFree; // get volatile into temporary
#ifndef Q_UNSAFE
QEQueueCtr dis = static_cast&lt;QEQueueCtr&gt;(~m_eQueue.m_nFree_dis);
Q_INVARIANT_INCRIT(201, e-&gt;verify_() &amp;&amp; (tmp == dis));
#endif // ndef Q_UNSAFE

// test-probe#1 for faking queue overflow
QS_TEST_PROBE_DEF(&amp;QActive::post_)
QS_TEST_PROBE_ID(1,
    tmp = 0U; // fake no free events
)

// required margin available?
bool status;
if (margin == QF::NO_MARGIN) {
    if (tmp &gt; 0U) { // free entries available in the queue?
        status = true; // can post
    }
    else { // no free entries available
        status = false; // cannot post

        // The queue overflows, but QF_NO_MARGIN indicates that
        // the &quot;event delivery guarantee&quot; is required.
        Q_ERROR_INCRIT(210); // must be able to post the event
    }
}
else if (tmp &gt; static_cast&lt;QEQueueCtr&gt;(margin)) {
    status = true; // can post
}
else { // the # free entries below the requested margin
    status = false; // cannot post, but don't assert
}

// is it a mutable event?
if (e-&gt;getPoolNum_() != 0U) {
    QEvt_refCtr_inc_(e); // increment the reference counter
}

if (status) { // can post the event?
    --tmp; // one free entry just used up

    m_eQueue.m_nFree = tmp; // update the original
#ifndef Q_UNSAFE
    m_eQueue.m_nFree_dis = static_cast&lt;QEQueueCtr&gt;(~tmp);
#endif // ndef Q_UNSAFE

    if (m_eQueue.m_nMin &gt; tmp) {
        m_eQueue.m_nMin = tmp; // update minimum so far
    }

    QS_BEGIN_PRE(QS_QF_ACTIVE_POST, m_prio)
        QS_TIME_PRE();       // timestamp
        QS_OBJ_PRE(sender);  // the sender object
        QS_SIG_PRE(e-&gt;sig);  // the signal of the event
        QS_OBJ_PRE(this);    // this active object
        QS_2U8_PRE(e-&gt;getPoolNum_(), e-&gt;refCtr_);
        QS_EQC_PRE(tmp);   // # free entries
        QS_EQC_PRE(m_eQueue.m_nMin); // min # free entries
    QS_END_PRE()

#ifdef Q_UTEST
    // callback to examine the posted event under the same conditions
    // as producing the #QS_QF_ACTIVE_POST trace record, which are:
    // the local filter for this AO ('m_prio') is set
    if (QS_LOC_CHECK_(m_prio)) {
        QF_MEM_APP();
        QF_CRIT_EXIT();

        QS::onTestPost(sender, this, e, status);

        QF_CRIT_ENTRY();
        QF_MEM_SYS();
    }
#endif // def Q_UTEST

    if (m_eQueue.m_frontEvt == nullptr) { // is the queue empty?
        m_eQueue.m_frontEvt = e; // deliver event directly
#ifndef Q_UNSAFE
        Q_INVARIANT_INCRIT(211, m_eQueue.m_frontEvt_dis
            == static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(nullptr)));
        m_eQueue.m_frontEvt_dis =
            static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(e));
#endif // ndef Q_UNSAFE

#ifdef QXK_HPP_
        if (m_state.act == nullptr) { // eXtended thread?
            QXTHREAD_EQUEUE_SIGNAL_(this); // signal eXtended Thread
        }
        else {
            QACTIVE_EQUEUE_SIGNAL_(this); // signal the Active Object
        }
#else
        QACTIVE_EQUEUE_SIGNAL_(this); // signal the Active Object
#endif // def QXK_HPP_
    }
    else { // queue was not empty, insert event into the ring-buffer
        tmp = m_eQueue.m_head; // get volatile into temporary
#ifndef Q_UNSAFE
        dis = static_cast&lt;QEQueueCtr&gt;(~m_eQueue.m_head_dis);
        Q_INVARIANT_INCRIT(212, tmp == dis);
#endif // ndef Q_UNSAFE
        m_eQueue.m_ring[tmp] = e; // insert e into buffer

        if (tmp == 0U) { // need to wrap the head?
            tmp = m_eQueue.m_end;
        }
        --tmp; // advance the head (counter-clockwise)

        m_eQueue.m_head = tmp; // update the original
#ifndef Q_UNSAFE
        m_eQueue.m_head_dis = static_cast&lt;QEQueueCtr&gt;(~tmp);
#endif // ndef Q_UNSAFE
    }

    QF_MEM_APP();
    QF_CRIT_EXIT();
}
else { // event cannot be posted

    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-&gt;sig);  // the signal of the event
        QS_OBJ_PRE(this);    // this active object
        QS_2U8_PRE(e-&gt;getPoolNum_(), e-&gt;refCtr_);
        QS_EQC_PRE(tmp);     // # free entries
        QS_EQC_PRE(margin);  // margin requested
    QS_END_PRE()

#ifdef Q_UTEST
    // callback to examine the posted event under the same conditions
    // as producing the #QS_QF_ACTIVE_POST trace record, which are:
    // the local filter for this AO ('m_prio') is set
    if (QS_LOC_CHECK_(m_prio)) {
        QF_MEM_APP();
        QF_CRIT_EXIT();

        QS::onTestPost(sender, this, e, status);

        QF_CRIT_ENTRY();
        QF_MEM_SYS();
    }
#endif // def Q_USTEST

    QF_MEM_APP();
    QF_CRIT_EXIT();

#if (QF_MAX_EPOOL &gt; 0U)
    QF::gc(e); // recycle the event to avoid a leak
#endif // (QF_MAX_EPOOL &gt; 0U)
}

return status;</code>
   </operation>
   <!--${QF::QActive::postLIFO}-->
   <operation name="postLIFO" type="void" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QActive::postLIFO::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <code>#ifdef Q_UTEST // test?
#if (Q_UTEST != 0) // testing QP-stub?
if (m_temp.fun == Q_STATE_CAST(0)) { // QActiveDummy?
    static_cast&lt;QActiveDummy *&gt;(this)-&gt;QActiveDummy::fakePostLIFO(e);
    return;
}
#endif // (Q_UTEST != 0)
#endif // def Q_UTEST

QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_REQUIRE_INCRIT(300, e != nullptr);

QEQueueCtr tmp = m_eQueue.m_nFree; // get volatile into temporary
#ifndef Q_UNSAFE
QEQueueCtr dis = static_cast&lt;QEQueueCtr&gt;(~m_eQueue.m_nFree_dis);
Q_INVARIANT_INCRIT(301, e-&gt;verify_() &amp;&amp; (tmp == dis));
#endif // ndef Q_UNSAFE

// test-probe#1 for faking queue overflow
QS_TEST_PROBE_DEF(&amp;QActive::postLIFO)
QS_TEST_PROBE_ID(1,
    tmp = 0U; // fake no free events
)

// The queue must NOT overflow for the LIFO posting policy.
Q_REQUIRE_INCRIT(310, tmp != 0U);

if (e-&gt;getPoolNum_() != 0U) {
    QEvt_refCtr_inc_(e); // increment the reference counter
}

--tmp; // one free entry just used up

m_eQueue.m_nFree = tmp; // update the original
#ifndef Q_UNSAFE
m_eQueue.m_nFree_dis = static_cast&lt;QEQueueCtr&gt;(~tmp);
#endif // ndef Q_UNSAFE

if (m_eQueue.m_nMin &gt; tmp) {
    m_eQueue.m_nMin = tmp; // update minimum so far
}

QS_BEGIN_PRE(QS_QF_ACTIVE_POST_LIFO, m_prio)
    QS_TIME_PRE();       // timestamp
    QS_SIG_PRE(e-&gt;sig);  // the signal of this event
    QS_OBJ_PRE(this);    // this active object
    QS_2U8_PRE(e-&gt;getPoolNum_(), e-&gt;refCtr_);
    QS_EQC_PRE(tmp);     // # free entries
    QS_EQC_PRE(m_eQueue.m_nMin); // min # free entries
QS_END_PRE()

#ifdef Q_UTEST
// callback to examine the posted event under the same conditions
// as producing the #QS_QF_ACTIVE_POST trace record, which are:
// the local filter for this AO ('m_prio') is set
if (QS_LOC_CHECK_(m_prio)) {
    QF_MEM_APP();
    QF_CRIT_EXIT();

    QS::onTestPost(nullptr, this, e, true);

    QF_CRIT_ENTRY();
    QF_MEM_SYS();
}
#endif // def Q_UTEST

QEvt const * const frontEvt = m_eQueue.m_frontEvt;
m_eQueue.m_frontEvt = e; // deliver the event directly to the front
#ifndef Q_UNSAFE
m_eQueue.m_frontEvt_dis =
    static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(e));
#endif // ndef Q_UNSAFE

if (frontEvt != nullptr) { // was the queue NOT empty?
    tmp = m_eQueue.m_tail; // get volatile into temporary;
#ifndef Q_UNSAFE
    dis = static_cast&lt;QEQueueCtr&gt;(~m_eQueue.m_tail_dis);
    Q_INVARIANT_INCRIT(311, tmp == dis);
#endif // ndef Q_UNSAFE
    ++tmp;
    if (tmp == m_eQueue.m_end) { // need to wrap the tail?
        tmp = 0U; // wrap around
    }
    m_eQueue.m_tail = tmp;
#ifndef Q_UNSAFE
    m_eQueue.m_tail_dis = static_cast&lt;QEQueueCtr&gt;(~tmp);
#endif // ndef Q_UNSAFE
    m_eQueue.m_ring[tmp] = frontEvt;
}
else { // queue was empty
    QACTIVE_EQUEUE_SIGNAL_(this); // signal the event queue
}

QF_MEM_APP();
QF_CRIT_EXIT();</code>
   </operation>
   <!--${QF::QActive::get_}-->
   <operation name="get_" type="QEvt const *" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

// wait for event to arrive directly (depends on QP port)
// NOTE: might use assertion-IDs 400-409
QACTIVE_EQUEUE_WAIT_(this); // wait for event to arrive directly

// always remove evt from the front
QEvt const * const e = m_eQueue.m_frontEvt;
QEQueueCtr tmp = m_eQueue.m_nFree; // get volatile into tmp

#ifndef Q_UNSAFE
Q_INVARIANT_INCRIT(410, e != nullptr); // queue must NOT be empty
Q_INVARIANT_INCRIT(411, Q_PTR2UINT_CAST_(e)
    == static_cast&lt;std::uintptr_t&gt;(~m_eQueue.m_frontEvt_dis));
QEQueueCtr dis = static_cast&lt;QEQueueCtr&gt;(~m_eQueue.m_nFree_dis);
Q_INVARIANT_INCRIT(412, tmp == dis);
#endif // ndef Q_UNSAFE

++tmp; // one more free event in the queue

m_eQueue.m_nFree = tmp; // update the # free
#ifndef Q_UNSAFE
m_eQueue.m_nFree_dis = static_cast&lt;QEQueueCtr&gt;(~tmp);
#endif // ndef Q_UNSAFE

if (tmp &lt;= m_eQueue.m_end) { // any events in the ring buffer?
    QS_BEGIN_PRE(QS_QF_ACTIVE_GET, m_prio)
        QS_TIME_PRE();       // timestamp
        QS_SIG_PRE(e-&gt;sig);  // the signal of this event
        QS_OBJ_PRE(this);    // this active object
        QS_2U8_PRE(e-&gt;getPoolNum_(), e-&gt;refCtr_);
        QS_EQC_PRE(tmp);     // # free entries
    QS_END_PRE()

    // remove event from the tail
    tmp = m_eQueue.m_tail; // get volatile into temporary
#ifndef Q_UNSAFE
    dis = static_cast&lt;QEQueueCtr&gt;(~m_eQueue.m_tail_dis);
    Q_INVARIANT_INCRIT(420, tmp == dis);
#endif // ndef Q_UNSAFE
    QEvt const * const frontEvt = m_eQueue.m_ring[tmp];
#ifndef Q_UNSAFE
    Q_ASSERT_INCRIT(421, frontEvt != nullptr);
    m_eQueue.m_frontEvt_dis =
        static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(frontEvt));
#endif // ndef Q_UNSAFE
    m_eQueue.m_frontEvt = frontEvt; // update the original

    if (tmp == 0U) { // need to wrap the tail?
        tmp = m_eQueue.m_end;
    }
    --tmp; // advance the tail (counter-clockwise)

    m_eQueue.m_tail = tmp; // update the original
#ifndef Q_UNSAFE
    m_eQueue.m_tail_dis = static_cast&lt;QEQueueCtr&gt;(~tmp);
#endif // ndef Q_UNSAFE
}
else {
    m_eQueue.m_frontEvt = nullptr; // the queue becomes empty
#ifndef Q_UNSAFE
    m_eQueue.m_frontEvt_dis =
        static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(nullptr));
#endif // ndef Q_UNSAFE

    // all entries in the queue must be free (+1 for fronEvt)
    Q_ASSERT_INCRIT(310, tmp == (m_eQueue.m_end + 1U));

    QS_BEGIN_PRE(QS_QF_ACTIVE_GET_LAST, m_prio)
        QS_TIME_PRE();       // timestamp
        QS_SIG_PRE(e-&gt;sig);  // the signal of this event
        QS_OBJ_PRE(this);    // this active object
        QS_2U8_PRE(e-&gt;getPoolNum_(), e-&gt;refCtr_);
    QS_END_PRE()
}

QF_MEM_APP();
QF_CRIT_EXIT();

return e;</code>
   </operation>
   <!--${QF::QActive::getQueueMin}-->
   <operation name="getQueueMin" type="std::uint_fast16_t" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QF::QActive::getQueueMin::prio}-->
    <parameter name="prio" type="std::uint_fast8_t const"/>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
Q_REQUIRE_INCRIT(400, (prio &lt;= QF_MAX_ACTIVE)
                  &amp;&amp; (QActive::registry_[prio] != nullptr));
std::uint_fast16_t const min = static_cast&lt;std::uint_fast16_t&gt;(
    QActive::registry_[prio]-&gt;m_eQueue.getNMin());
QF_CRIT_EXIT();

return min;</code>
   </operation>
   <!--${QF::QActive::psInit}-->
   <operation name="psInit" type="void" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QF::QActive::psInit::subscrSto}-->
    <parameter name="subscrSto" type="QSubscrList * const"/>
    <!--${QF::QActive::psInit::maxSignal}-->
    <parameter name="maxSignal" type="enum_t const"/>
    <code>subscrList_   = subscrSto;
maxPubSignal_ = maxSignal;

// initialize the subscriber list
for (enum_t sig = 0; sig &lt; maxSignal; ++sig) {
    subscrSto[sig].m_set.setEmpty();
#ifndef Q_UNSAFE
    subscrSto[sig].m_set.update_(&amp;subscrSto[sig].m_set_dis);
#endif
}</code>
   </operation>
   <!--${QF::QActive::publish_}-->
   <operation name="publish_" type="void" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QF::QActive::publish_::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <!--${QF::QActive::publish_::sender}-->
    <parameter name="sender" type="void const * const"/>
    <!--${QF::QActive::publish_::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>#ifndef Q_SPY
Q_UNUSED_PAR(sender);
Q_UNUSED_PAR(qsId);
#endif

QSignal const sig = e-&gt;sig;

QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_REQUIRE_INCRIT(200, sig &lt; static_cast&lt;QSignal&gt;(maxPubSignal_));
Q_INVARIANT_INCRIT(202,
    subscrList_[sig].m_set.verify_(&amp;subscrList_[sig].m_set_dis));

QS_BEGIN_PRE(QS_QF_PUBLISH, qsId)
    QS_TIME_PRE();          // the timestamp
    QS_OBJ_PRE(sender);     // the sender object
    QS_SIG_PRE(e-&gt;sig);     // the signal of the event
    QS_2U8_PRE(e-&gt;getPoolNum_(), e-&gt;refCtr_);
QS_END_PRE()

// is it a mutable event?
if (e-&gt;getPoolNum_() != 0U) {
    // NOTE: The reference counter of a mutable event is incremented to
    // prevent premature recycling of the event while the multicasting
    // is still in progress. At the end of the function, the garbage
    // collector step (QF::gc()) decrements the reference counter and
    // recycles the event if the counter drops to zero. This covers the
    // case when the event was published without any subscribers.
    QEvt_refCtr_inc_(e);
}

// make a local, modifiable copy of the subscriber set
QPSet subscrSet = subscrList_[sig].m_set;

QF_MEM_APP();
QF_CRIT_EXIT();

if (subscrSet.notEmpty()) { // any subscribers?
    // highest-prio subscriber
    std::uint_fast8_t p = subscrSet.findMax();

    QF_CRIT_ENTRY();
    QF_MEM_SYS();

    QActive *a = registry_[p];
    // the AO must be registered with the framework
    Q_ASSERT_INCRIT(210, a != nullptr);

    QF_MEM_APP();
    QF_CRIT_EXIT();

    QF_SCHED_STAT_
    QF_SCHED_LOCK_(p); // lock the scheduler up to AO's prio
    std::uint_fast8_t lbound = QF_MAX_ACTIVE + 1U;
    do { // loop over all subscribers
        --lbound;

        // POST() asserts internally if the queue overflows
        a-&gt;POST(e, sender);

        subscrSet.remove(p); // remove the handled subscriber
        if (subscrSet.notEmpty()) {  // still more subscribers?
            p = subscrSet.findMax(); // highest-prio subscriber

            QF_CRIT_ENTRY();
            QF_MEM_SYS();

            a = registry_[p];
            // the AO must be registered with the framework
            Q_ASSERT_INCRIT(220, a != nullptr);

            QF_MEM_APP();
            QF_CRIT_EXIT();
        }
        else {
            p = 0U; // no more subscribers
        }
    } while ((p != 0U) &amp;&amp; (lbound &gt; 0U));

    QF_CRIT_ENTRY();
    Q_ENSURE_INCRIT(290, p == 0U);
    QF_CRIT_EXIT();

    QF_SCHED_UNLOCK_(); // unlock the scheduler
}

// The following garbage collection step decrements the reference counter
// and recycles the event if the counter drops to zero. This covers both
// cases when the event was published with or without any subscribers.
#if (QF_MAX_EPOOL &gt; 0U)
QF::gc(e);
#endif</code>
   </operation>
   <!--${QF::QActive::subscribe}-->
   <operation name="subscribe" type="void" visibility="0x00" properties="0x00">
    <specifiers>const noexcept</specifiers>
    <!--${QF::QActive::subscribe::sig}-->
    <parameter name="sig" type="enum_t const"/>
    <code>std::uint_fast8_t const p = static_cast&lt;std::uint_fast8_t&gt;(m_prio);

QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_REQUIRE_INCRIT(300, (Q_USER_SIG &lt;= sig)
    &amp;&amp; (sig &lt; maxPubSignal_)
    &amp;&amp; (0U &lt; p) &amp;&amp; (p &lt;= QF_MAX_ACTIVE)
    &amp;&amp; (registry_[p] == this));
Q_INVARIANT_INCRIT(302,
    subscrList_[sig].m_set.verify_(&amp;subscrList_[sig].m_set_dis));

QS_BEGIN_PRE(QS_QF_ACTIVE_SUBSCRIBE, m_prio)
    QS_TIME_PRE();    // timestamp
    QS_SIG_PRE(sig);  // the signal of this event
    QS_OBJ_PRE(this); // this active object
QS_END_PRE()

// insert the prio. into the subscriber set
subscrList_[sig].m_set.insert(p);
#ifndef Q_UNSAFE
subscrList_[sig].m_set.update_(&amp;subscrList_[sig].m_set_dis);
#endif

QF_MEM_APP();
QF_CRIT_EXIT();</code>
   </operation>
   <!--${QF::QActive::unsubscribe}-->
   <operation name="unsubscribe" type="void" visibility="0x00" properties="0x00">
    <specifiers>const noexcept</specifiers>
    <!--${QF::QActive::unsubscribe::sig}-->
    <parameter name="sig" type="enum_t const"/>
    <code>std::uint_fast8_t const p = static_cast&lt;std::uint_fast8_t&gt;(m_prio);

QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_REQUIRE_INCRIT(400, (Q_USER_SIG &lt;= sig)
    &amp;&amp; (sig &lt; maxPubSignal_)
    &amp;&amp; (0U &lt; p) &amp;&amp; (p &lt;= QF_MAX_ACTIVE)
    &amp;&amp; (registry_[p] == this));
Q_INVARIANT_INCRIT(402,
    subscrList_[sig].m_set.verify_(&amp;subscrList_[sig].m_set_dis));

QS_BEGIN_PRE(QS_QF_ACTIVE_UNSUBSCRIBE, m_prio)
    QS_TIME_PRE();    // timestamp
    QS_SIG_PRE(sig);  // the signal of this event
    QS_OBJ_PRE(this); // this active object
QS_END_PRE()

// remove the prio. from the subscriber set
subscrList_[sig].m_set.remove(p);
#ifndef Q_UNSAFE
subscrList_[sig].m_set.update_(&amp;subscrList_[sig].m_set_dis);
#endif

QF_MEM_APP();
QF_CRIT_EXIT();</code>
   </operation>
   <!--${QF::QActive::unsubscribeAll}-->
   <operation name="unsubscribeAll" type="void" visibility="0x00" properties="0x00">
    <specifiers>const noexcept</specifiers>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

std::uint_fast8_t const p = static_cast&lt;std::uint_fast8_t&gt;(m_prio);

Q_REQUIRE_INCRIT(500, (0U &lt; p) &amp;&amp; (p &lt;= QF_MAX_ACTIVE)
                       &amp;&amp; (registry_[p] == this));
enum_t const maxPubSig = maxPubSignal_;

QF_MEM_APP();
QF_CRIT_EXIT();

for (enum_t sig = Q_USER_SIG; sig &lt; maxPubSig; ++sig) {
    QF_CRIT_ENTRY();
    QF_MEM_SYS();

    if (subscrList_[sig].m_set.hasElement(p)) {
        subscrList_[sig].m_set.remove(p);
#ifndef Q_UNSAFE
        subscrList_[sig].m_set.update_(&amp;subscrList_[sig].m_set_dis);
#endif
        QS_BEGIN_PRE(QS_QF_ACTIVE_UNSUBSCRIBE, m_prio)
            QS_TIME_PRE();    // timestamp
            QS_SIG_PRE(sig);  // the signal of this event
            QS_OBJ_PRE(this); // this active object
        QS_END_PRE()
    }
    QF_MEM_APP();
    QF_CRIT_EXIT();

    QF_CRIT_EXIT_NOP(); // prevent merging critical sections
}</code>
   </operation>
   <!--${QF::QActive::defer}-->
   <operation name="defer" type="bool" visibility="0x00" properties="0x00">
    <specifiers>const noexcept</specifiers>
    <!--${QF::QActive::defer::eq}-->
    <parameter name="eq" type="QEQueue * const"/>
    <!--${QF::QActive::defer::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <code>bool const status = eq-&gt;post(e, 0U, m_prio);

QS_CRIT_STAT
QS_CRIT_ENTRY();
QS_MEM_SYS();
QS_BEGIN_PRE(QS_QF_ACTIVE_DEFER, m_prio)
    QS_TIME_PRE();      // time stamp
    QS_OBJ_PRE(this);   // this active object
    QS_OBJ_PRE(eq);     // the deferred queue
    QS_SIG_PRE(e-&gt;sig); // the signal of the event
    QS_2U8_PRE(e-&gt;getPoolNum_(), e-&gt;refCtr_);
QS_END_PRE()
QS_MEM_APP();
QS_CRIT_EXIT();

return status;</code>
   </operation>
   <!--${QF::QActive::recall}-->
   <operation name="recall" type="bool" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QActive::recall::eq}-->
    <parameter name="eq" type="QEQueue * const"/>
    <code>QEvt const * const e = eq-&gt;get(m_prio); // get evt from deferred queue
QF_CRIT_STAT

bool recalled;
if (e != nullptr) { // event available?
    postLIFO(e); // post it to the _front_ of the AO's queue

    QF_CRIT_ENTRY();
    QF_MEM_SYS();

    if (e-&gt;getPoolNum_() != 0U) { // is it a mutable event?

        // after posting to the AO's queue the event must be referenced
        // at least twice: once in the deferred event queue (eq-&gt;get()
        // did NOT decrement the reference counter) and once in the
        // AO's event queue.
        Q_ASSERT_INCRIT(210, e-&gt;refCtr_ &gt;= 2U);

        // we need to decrement the reference counter once, to account
        // for removing the event from the deferred event queue.
        QEvt_refCtr_dec_(e); // decrement the reference counter
    }

    QS_BEGIN_PRE(QS_QF_ACTIVE_RECALL, m_prio)
        QS_TIME_PRE();      // time stamp
        QS_OBJ_PRE(this);   // this active object
        QS_OBJ_PRE(eq);     // the deferred queue
        QS_SIG_PRE(e-&gt;sig); // the signal of the event
        QS_2U8_PRE(e-&gt;getPoolNum_(), e-&gt;refCtr_);
    QS_END_PRE()

    QF_MEM_APP();
    QF_CRIT_EXIT();

    recalled = true;
}
else {
    QS_CRIT_ENTRY();
    QS_MEM_SYS();

    QS_BEGIN_PRE(QS_QF_ACTIVE_RECALL_ATTEMPT, m_prio)
        QS_TIME_PRE();      // time stamp
        QS_OBJ_PRE(this);   // this active object
        QS_OBJ_PRE(eq);     // the deferred queue
    QS_END_PRE()

    QS_MEM_APP();
    QS_CRIT_EXIT();

    recalled = false;
}
return recalled;</code>
   </operation>
   <!--${QF::QActive::flushDeferred}-->
   <operation name="flushDeferred" type="std::uint_fast16_t" visibility="0x00" properties="0x00">
    <specifiers>const noexcept</specifiers>
    <!--${QF::QActive::flushDeferred::eq}-->
    <parameter name="eq" type="QEQueue * const"/>
    <!--${QF::QActive::flushDeferred::num = 0xFFFFU}-->
    <parameter name="num = 0xFFFFU" type="std::uint_fast16_t const"/>
    <code>std::uint_fast16_t n = 0U;
while (n &lt; num) {
    QEvt const * const e = eq-&gt;get(m_prio);
    if (e != nullptr) {
        ++n; // count one more flushed event
#if (QF_MAX_EPOOL &gt; 0U)
        QF::gc(e); // garbage collect
#endif
    }
    else {
        break;
    }
}

return n;</code>
   </operation>
   <!--${QF::QActive::getPrio}-->
   <operation name="getPrio" type="std::uint_fast8_t" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>return static_cast&lt;std::uint_fast8_t&gt;(m_prio);</code>
   </operation>
   <!--${QF::QActive::setPrio}-->
   <operation name="setPrio" type="void" visibility="0x00" properties="0x02">
    <specifiers>noexcept</specifiers>
    <!--${QF::QActive::setPrio::prio}-->
    <parameter name="prio" type="QPrioSpec const"/>
    <code>m_prio  = static_cast&lt;std::uint8_t&gt;(prio &amp; 0xFFU);
m_pthre = static_cast&lt;std::uint8_t&gt;(prio &gt;&gt; 8U);</code>
   </operation>
   <!--${QF::QActive::getPThre}-->
   <operation name="getPThre" type="std::uint_fast8_t" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>return static_cast&lt;std::uint_fast8_t&gt;(m_pthre);</code>
   </operation>
   <!--${QF::QActive::getEQueue}-->
   <operation name="getEQueue?def QACTIVE_EQUEUE_TYPE" type="QACTIVE_EQUEUE_TYPE const &amp;" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>return m_eQueue;</code>
   </operation>
   <!--${QF::QActive::getOsObject}-->
   <operation name="getOsObject?def QACTIVE_OS_OBJ_TYPE" type="QACTIVE_OS_OBJ_TYPE const &amp;" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>return m_osObject;</code>
   </operation>
   <!--${QF::QActive::getThread}-->
   <operation name="getThread?def QACTIVE_THREAD_TYPE" type="QACTIVE_THREAD_TYPE const &amp;" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>return m_thread;</code>
   </operation>
   <!--${QF::QActive::setThread}-->
   <operation name="setThread?def QACTIVE_THREAD_TYPE" type="void" visibility="0x00" properties="0x02">
    <!--${QF::QActive::setThread::thr}-->
    <parameter name="thr" type="QACTIVE_THREAD_TYPE const &amp;"/>
    <code>m_thread = thr;</code>
   </operation>
   <!--${QF::QActive::evtLoop_}-->
   <operation name="evtLoop_" type="void" visibility="0x00" properties="0x01">
    <!--${QF::QActive::evtLoop_::act}-->
    <parameter name="act" type="QActive *"/>
   </operation>
   <!--${QF::QActive::postFromISR}-->
   <operation name="postFromISR?def QF_ISR_API" type="bool" visibility="0x00" properties="0x04">
    <specifiers>noexcept</specifiers>
    <!--${QF::QActive::postFromISR::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <!--${QF::QActive::postFromISR::margin}-->
    <parameter name="margin" type="std::uint_fast16_t const"/>
    <!--${QF::QActive::postFromISR::par}-->
    <parameter name="par" type="void *"/>
    <!--${QF::QActive::postFromISR::sender}-->
    <parameter name="sender" type="void const * const"/>
   </operation>
   <!--${QF::QActive::publishFromISR}-->
   <operation name="publishFromISR?def QF_ISR_API" type="void" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QF::QActive::publishFromISR::e}-->
    <parameter name="e" type="QEvt const *"/>
    <!--${QF::QActive::publishFromISR::par}-->
    <parameter name="par" type="void *"/>
    <!--${QF::QActive::publishFromISR::sender}-->
    <parameter name="sender" type="void const *"/>
   </operation>
  </class>
  <!--${QF::QMActive}-->
  <class name="QMActive" superclass="QF::QActive">
   <!--${QF::QMActive::QMActive}-->
   <operation name="QMActive" type="" visibility="0x01" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QMActive::QMActive::initial}-->
    <parameter name="initial" type="QStateHandler const"/>
    <code>  : QActive(initial)

m_state.obj = reinterpret_cast&lt;QMsm *&gt;(this)-&gt;topQMState();
m_temp.fun  = initial;</code>
   </operation>
   <!--${QF::QMActive::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x02">
    <specifiers>override</specifiers>
    <!--${QF::QMActive::init::e}-->
    <parameter name="e" type="void const * const"/>
    <!--${QF::QMActive::init::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>reinterpret_cast&lt;QMsm *&gt;(this)-&gt;QMsm::init(e, qsId);</code>
   </operation>
   <!--${QF::QMActive::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x06">
    <specifiers>override</specifiers>
    <!--${QF::QMActive::init::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>this-&gt;init(nullptr, qsId);</code>
   </operation>
   <!--${QF::QMActive::dispatch}-->
   <operation name="dispatch" type="void" visibility="0x00" properties="0x02">
    <specifiers>override</specifiers>
    <!--${QF::QMActive::dispatch::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <!--${QF::QMActive::dispatch::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>reinterpret_cast&lt;QMsm *&gt;(this)-&gt;QMsm::dispatch(e, qsId);</code>
   </operation>
   <!--${QF::QMActive::isIn}-->
   <operation name="isIn" type="bool" visibility="0x00" properties="0x02">
    <specifiers>noexcept override</specifiers>
    <!--${QF::QMActive::isIn::state}-->
    <parameter name="state" type="QStateHandler const"/>
    <code>return reinterpret_cast&lt;QMsm *&gt;(this)-&gt;QMsm::isIn(state);</code>
   </operation>
   <!--${QF::QMActive::getStateHandler}-->
   <operation name="getStateHandler?def Q_SPY" type="QStateHandler" visibility="0x00" properties="0x02">
    <specifiers>noexcept override</specifiers>
    <code>return reinterpret_cast&lt;QMsm *&gt;(this)-&gt;QMsm::getStateHandler();</code>
   </operation>
   <!--${QF::QMActive::childStateObj}-->
   <operation name="childStateObj" type="QMState const *" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <!--${QF::QMActive::childStateObj::parent}-->
    <parameter name="parent" type="QMState const * const"/>
    <code>return reinterpret_cast&lt;QMsm const *&gt;(this)
           -&gt;QMsm::childStateObj(parent);</code>
   </operation>
  </class>
  <!--${QF::QTimeEvt}-->
  <class name="QTimeEvt" superclass="QEP::QEvt">
   <!--${QF::QTimeEvt::m_next}-->
   <attribute name="m_next" type="QTimeEvt * volatile" visibility="0x02" properties="0x00"/>
   <!--${QF::QTimeEvt::m_next_dis}-->
   <attribute name="m_next_dis?ndef Q_UNSAFE" type="std::uintptr_t" visibility="0x02" properties="0x00"/>
   <!--${QF::QTimeEvt::m_act}-->
   <attribute name="m_act" type="void *" visibility="0x02" properties="0x00"/>
   <!--${QF::QTimeEvt::m_ctr}-->
   <attribute name="m_ctr" type="QTimeEvtCtr volatile" visibility="0x02" properties="0x00"/>
   <!--${QF::QTimeEvt::m_ctr_dis}-->
   <attribute name="m_ctr_dis?ndef Q_UNSAFE" type="QTimeEvtCtr" visibility="0x02" properties="0x00"/>
   <!--${QF::QTimeEvt::m_interval}-->
   <attribute name="m_interval" type="QTimeEvtCtr" visibility="0x02" properties="0x00"/>
   <!--${QF::QTimeEvt::m_tickRate}-->
   <attribute name="m_tickRate" type="std::uint8_t" visibility="0x02" properties="0x00"/>
   <!--${QF::QTimeEvt::m_flags}-->
   <attribute name="m_flags" type="std::uint8_t" visibility="0x02" properties="0x00"/>
   <!--${QF::QTimeEvt::timeEvtHead_[QF_MAX_TICK_RATE]}-->
   <attribute name="timeEvtHead_[QF_MAX_TICK_RATE]" type="QTimeEvt" visibility="0x00" properties="0x01"/>
   <!--${QF::QTimeEvt::timeEvtHead_dis_[QF_MAX_TICK_RAT~}-->
   <attribute name="timeEvtHead_dis_[QF_MAX_TICK_RATE]?ndef Q_UNSAFE" type="QPtrDis" visibility="0x00" properties="0x01"/>
   <!--${QF::QTimeEvt::QXThread}-->
   <attribute name="QXThread" type="friend class" visibility="0x02" properties="0x00"/>
   <!--${QF::QTimeEvt::QTimeEvt}-->
   <operation name="QTimeEvt" type="" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QTimeEvt::QTimeEvt::act}-->
    <parameter name="act" type="QActive * const"/>
    <!--${QF::QTimeEvt::QTimeEvt::sig}-->
    <parameter name="sig" type="QSignal const"/>
    <!--${QF::QTimeEvt::QTimeEvt::tickRate = 0U}-->
    <parameter name="tickRate = 0U" type="std::uint_fast8_t const"/>
    <code> :  QEvt(sig),
    m_next(nullptr),
#ifndef Q_UNSAFE
    m_next_dis(static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(nullptr))),
#endif
    m_act(act),
    m_ctr(0U),
#ifndef Q_UNSAFE
    m_ctr_dis(static_cast&lt;QTimeEvtCtr&gt;(~static_cast&lt;QTimeEvtCtr&gt;(0U))),
#endif
    m_interval(0U),
    m_tickRate(0U),
    m_flags(0U)

QF_CRIT_STAT
QF_CRIT_ENTRY();
Q_REQUIRE_INCRIT(300, (sig != 0U)
    &amp;&amp; (tickRate &lt; QF_MAX_TICK_RATE));
QF_CRIT_EXIT();

// adjust the settings from the QEvt(sig) ctor
evtTag_ = 0x0FU;
refCtr_ = 0U;</code>
   </operation>
   <!--${QF::QTimeEvt::armX}-->
   <operation name="armX" type="void" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QTimeEvt::armX::nTicks}-->
    <parameter name="nTicks" type="std::uint32_t const"/>
    <!--${QF::QTimeEvt::armX::interval = 0U}-->
    <parameter name="interval = 0U" type="std::uint32_t const"/>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

// dynamic range checks
#if (QF_TIMEEVT_CTR_SIZE == 1U)
Q_REQUIRE_INCRIT(400, (nTicks &lt; 0xFFU) &amp;&amp; (interval &lt; 0xFFU));
#elif (QF_TIMEEVT_CTR_SIZE == 2U)
Q_REQUIRE_INCRIT(400, (nTicks &lt; 0xFFFFU) &amp;&amp; (interval &lt; 0xFFFFU));
#endif

Q_REQUIRE_INCRIT(401, verify_() &amp;&amp; (nTicks != 0U));

QTimeEvtCtr const ctr = m_ctr;
std::uint8_t const tickRate = m_tickRate;
#ifdef Q_SPY
std::uint_fast8_t const qsId =
     static_cast&lt;QActive const *&gt;(m_act)-&gt;m_prio;
#endif // def Q_SPY

Q_REQUIRE_INCRIT(410, (ctr == 0U)
    &amp;&amp; (m_act != nullptr)
    &amp;&amp; (tickRate &lt; QF_MAX_TICK_RATE));

#ifndef Q_UNSAFE
Q_INVARIANT_INCRIT(411, ctr == static_cast&lt;QTimeEvtCtr&gt;(~m_ctr_dis));
#else
Q_UNUSED_PAR(ctr);
#endif // ndef Q_UNSAFE

m_ctr = static_cast&lt;QTimeEvtCtr&gt;(nTicks);
m_interval = static_cast&lt;QTimeEvtCtr&gt;(interval);
#ifndef Q_UNSAFE
m_ctr_dis = static_cast&lt;QTimeEvtCtr&gt;(~nTicks);
#endif // ndef Q_UNSAFE

// is the time event unlinked?
// NOTE: For the duration of a single clock tick of the specified tick
// rate a time event can be disarmed and yet still linked into the list
// because un-linking is performed exclusively in the QF_tickX() function.
if ((m_flags &amp; QTE_FLAG_IS_LINKED) == 0U) {
    m_flags |= QTE_FLAG_IS_LINKED; // mark as linked

    // The time event is initially inserted into the separate
    // &quot;freshly armed&quot; list based on timeEvtHead_[tickRate].act.
    // Only later, inside QTimeEvt::tick(), the &quot;freshly armed&quot;
    // list is appended to the main list of armed time events based on
    // timeEvtHead_[tickRate].next. Again, this is to keep any
    // changes to the main list exclusively inside QTimeEvt::tick().
#ifndef Q_UNSAFE
    Q_INVARIANT_INCRIT(420,
        Q_PTR2UINT_CAST_(m_next) ==
        static_cast&lt;std::uintptr_t&gt;(~m_next_dis));
    Q_INVARIANT_INCRIT(411,
        Q_PTR2UINT_CAST_(timeEvtHead_[tickRate].m_act) ==
        static_cast&lt;std::uintptr_t&gt;(~timeEvtHead_dis_[tickRate].m_ptr_dis));
#endif
    m_next = timeEvtHead_[tickRate].toTimeEvt();
    timeEvtHead_[tickRate].m_act = this;
#ifndef Q_UNSAFE
    m_next_dis =
        static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(m_next));
    timeEvtHead_dis_[tickRate].m_ptr_dis =
        static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(this));
#endif // ndef Q_UNSAFE
}

QS_BEGIN_PRE(QS_QF_TIMEEVT_ARM, qsId)
    QS_TIME_PRE();        // timestamp
    QS_OBJ_PRE(this);     // this time event object
    QS_OBJ_PRE(m_act);    // the active object
    QS_TEC_PRE(nTicks);   // the # ticks
    QS_TEC_PRE(interval); // the interval
    QS_U8_PRE(tickRate);  // tick rate
QS_END_PRE()

QF_MEM_APP();
QF_CRIT_EXIT();</code>
   </operation>
   <!--${QF::QTimeEvt::disarm}-->
   <operation name="disarm" type="bool" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_REQUIRE_INCRIT(500, verify_());

QTimeEvtCtr const ctr = m_ctr;
#ifndef Q_UNSAFE
Q_INVARIANT_INCRIT(501, ctr == static_cast&lt;QTimeEvtCtr&gt;(~m_ctr_dis));
#endif // ndef Q_UNSAFE

#ifdef Q_SPY
std::uint_fast8_t const qsId = static_cast&lt;QActive *&gt;(m_act)-&gt;m_prio;
#endif

// was the time event actually armed?
bool wasArmed;
if (ctr != 0U) {
    wasArmed = true;
    m_flags |= QTE_FLAG_WAS_DISARMED;
    m_ctr = 0U; // schedule removal from the list
#ifndef Q_UNSAFE
    m_ctr_dis = static_cast&lt;QTimeEvtCtr&gt;(~static_cast&lt;QTimeEvtCtr&gt;(0U));
#endif // ndef Q_UNSAFE

    QS_BEGIN_PRE(QS_QF_TIMEEVT_DISARM, qsId)
        QS_TIME_PRE();            // timestamp
        QS_OBJ_PRE(this);         // this time event object
        QS_OBJ_PRE(m_act);        // the target AO
        QS_TEC_PRE(ctr);          // the # ticks
        QS_TEC_PRE(m_interval);   // the interval
        QS_U8_PRE(m_tickRate);    // tick rate
    QS_END_PRE()
}
else { // the time event was already disarmed automatically
    wasArmed = false;
    m_flags &amp;= static_cast&lt;std::uint8_t&gt;(~QTE_FLAG_WAS_DISARMED);

    QS_BEGIN_PRE(QS_QF_TIMEEVT_DISARM_ATTEMPT, qsId)
        QS_TIME_PRE();            // timestamp
        QS_OBJ_PRE(this);         // this time event object
        QS_OBJ_PRE(m_act);        // the target AO
        QS_U8_PRE(m_tickRate);    // tick rate
    QS_END_PRE()
}

QF_MEM_APP();
QF_CRIT_EXIT();

return wasArmed;</code>
   </operation>
   <!--${QF::QTimeEvt::rearm}-->
   <operation name="rearm" type="bool" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QTimeEvt::rearm::nTicks}-->
    <parameter name="nTicks" type="std::uint32_t const"/>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

// dynamic range checks
#if (QF_TIMEEVT_CTR_SIZE == 1U)
Q_REQUIRE_INCRIT(600, nTicks &lt; 0xFFU);
#elif (QF_TIMEEVT_CTR_SIZE == 2U)
Q_REQUIRE_INCRIT(600, nTicks &lt; 0xFFFFU);
#endif

Q_REQUIRE_INCRIT(601, verify_() &amp;&amp; (nTicks != 0U));

QTimeEvtCtr const ctr = m_ctr;
std::uint8_t const tickRate = m_tickRate;
#ifdef Q_SPY
std::uint_fast8_t const qsId = static_cast&lt;QActive *&gt;(m_act)-&gt;m_prio;
#endif

Q_REQUIRE_INCRIT(610, (m_act != nullptr)
    &amp;&amp; (tickRate &lt; QF_MAX_TICK_RATE));

#ifndef Q_UNSAFE
Q_INVARIANT_INCRIT(602, ctr == static_cast&lt;QTimeEvtCtr&gt;(~m_ctr_dis));
#endif // ndef Q_UNSAFE
m_ctr = static_cast&lt;QTimeEvtCtr&gt;(nTicks);
#ifndef Q_UNSAFE
m_ctr_dis = static_cast&lt;QTimeEvtCtr&gt;(~nTicks);
#endif // ndef Q_UNSAFE

// is the time evt not running?
bool wasArmed;
if (ctr == 0U) {
    wasArmed = false;

    // NOTE: For a duration of a single clock tick of the specified
    // tick rate a time event can be disarmed and yet still linked into
    // the list, because unlinking is performed exclusively in the
    // QTimeEvt::tick() function.

    // was the time event unlinked?
    if ((m_flags &amp; QTE_FLAG_IS_LINKED) == 0U) {
        m_flags |= QTE_FLAG_IS_LINKED; // mark as linked

        // The time event is initially inserted into the separate
        // &quot;freshly armed&quot; list based on timeEvtHead_[tickRate].act.
        // Only later, inside QTimeEvt::tick(), the &quot;freshly armed&quot;
        // list is appended to the main list of armed time events based on
        // timeEvtHead_[tickRate].next. Again, this is to keep any
        // changes to the main list exclusively inside QTimeEvt::tick().
#ifndef Q_UNSAFE
    Q_INVARIANT_INCRIT(620,
        Q_PTR2UINT_CAST_(m_next) ==
        static_cast&lt;std::uintptr_t&gt;(~m_next_dis));
    Q_INVARIANT_INCRIT(611,
        Q_PTR2UINT_CAST_(timeEvtHead_[tickRate].m_act) ==
        static_cast&lt;std::uintptr_t&gt;(~timeEvtHead_dis_[tickRate].m_ptr_dis));
#endif
        m_next = timeEvtHead_[tickRate].toTimeEvt();
        timeEvtHead_[tickRate].m_act = this;
#ifndef Q_UNSAFE
        m_next_dis =
            static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(m_next));
        timeEvtHead_dis_[tickRate].m_ptr_dis =
            static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(this));
#endif // ndef Q_UNSAFE
    }
}
else { // the time event was armed
    wasArmed = true;
}

QS_BEGIN_PRE(QS_QF_TIMEEVT_REARM, qsId)
    QS_TIME_PRE();            // timestamp
    QS_OBJ_PRE(this);         // this time event object
    QS_OBJ_PRE(m_act);        // the target AO
    QS_TEC_PRE(nTicks);       // the # ticks
    QS_TEC_PRE(m_interval);   // the interval
    QS_2U8_PRE(tickRate, (wasArmed ? 1U : 0U));
QS_END_PRE()

QF_MEM_APP();
QF_CRIT_EXIT();

return wasArmed;</code>
   </operation>
   <!--${QF::QTimeEvt::wasDisarmed}-->
   <operation name="wasDisarmed" type="bool" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

bool const wasDisarmed = (m_flags &amp; QTE_FLAG_WAS_DISARMED) != 0U;
m_flags |= QTE_FLAG_WAS_DISARMED;

QF_MEM_APP();
QF_CRIT_EXIT();

return wasDisarmed;</code>
   </operation>
   <!--${QF::QTimeEvt::getAct}-->
   <operation name="getAct" type="void const *" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>return m_act;</code>
   </operation>
   <!--${QF::QTimeEvt::getCtr}-->
   <operation name="getCtr" type="QTimeEvtCtr" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>return m_ctr;</code>
   </operation>
   <!--${QF::QTimeEvt::getInterval}-->
   <operation name="getInterval" type="QTimeEvtCtr" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>return m_interval;</code>
   </operation>
   <!--${QF::QTimeEvt::getTickRate}-->
   <operation name="getTickRate" type="std::uint8_t" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>return m_tickRate;</code>
   </operation>
   <!--${QF::QTimeEvt::tick}-->
   <operation name="tick" type="void" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QF::QTimeEvt::tick::tickRate}-->
    <parameter name="tickRate" type="std::uint_fast8_t const"/>
    <!--${QF::QTimeEvt::tick::sender}-->
    <parameter name="sender" type="void const * const"/>
    <code>#ifndef Q_SPY
Q_UNUSED_PAR(sender);
#endif

QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_REQUIRE_INCRIT(800, tickRate &lt; Q_DIM(timeEvtHead_));

QTimeEvt *prev = &amp;timeEvtHead_[tickRate];

QS_BEGIN_PRE(QS_QF_TICK, 0U)
    prev-&gt;m_ctr = (prev-&gt;m_ctr + 1U);
    QS_TEC_PRE(prev-&gt;m_ctr); // tick ctr
    QS_U8_PRE(tickRate);     // tick rate
QS_END_PRE()

// scan the linked-list of time events at this rate...
std::uint_fast8_t lbound = 2U*QF_MAX_ACTIVE; // fixed upper loop bound
for (; lbound &gt; 0U; --lbound) {
    Q_ASSERT_INCRIT(810, prev != nullptr); // sanity check

    QTimeEvt *te = prev-&gt;m_next; // advance down the time evt. list
#ifndef Q_UNSAFE
    Q_INVARIANT_INCRIT(811,
        Q_PTR2UINT_CAST_(te) ==
            static_cast&lt;std::uintptr_t&gt;(~prev-&gt;m_next_dis));
#endif // ndef Q_UNSAFE

    if (te == nullptr) { // end of the list?

        // any new time events armed since the last QTimeEvt_tick_()?
        if (timeEvtHead_[tickRate].m_act != nullptr) {
#ifndef Q_UNSAFE
            Q_INVARIANT_INCRIT(812,
                Q_PTR2UINT_CAST_(timeEvtHead_[tickRate].m_act) ==
                static_cast&lt;std::uintptr_t&gt;(
                    ~timeEvtHead_dis_[tickRate].m_ptr_dis));
#endif // ndef Q_UNSAFE
            prev-&gt;m_next = timeEvtHead_[tickRate].toTimeEvt();
            timeEvtHead_[tickRate].m_act = nullptr;
#ifndef Q_UNSAFE
            prev-&gt;m_next_dis =
                static_cast&lt;std::uintptr_t&gt;(
                    ~Q_PTR2UINT_CAST_(prev-&gt;m_next));
            timeEvtHead_dis_[tickRate].m_ptr_dis =
                static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(nullptr));
#endif // ndef Q_UNSAFE

            te = prev-&gt;m_next; // switch to the new list
        }
        else { // all currently armed time events are processed
            break; // terminate the for-loop
        }
    }

    // the time event 'te' must be valid
    Q_ASSERT_INCRIT(820, te != nullptr);
    Q_INVARIANT_INCRIT(821, te-&gt;verify_());

    QTimeEvtCtr ctr = te-&gt;m_ctr;
#ifndef Q_UNSAFE
    Q_INVARIANT_INCRIT(822, ctr ==
        static_cast&lt;QTimeEvtCtr&gt;(~te-&gt;m_ctr_dis));
#endif // ndef Q_UNSAFE

    if (ctr == 0U) { // time event scheduled for removal?
        prev-&gt;m_next = te-&gt;m_next;
#ifndef Q_UNSAFE
        prev-&gt;m_next_dis =
            static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(te-&gt;m_next));
#endif // ndef Q_UNSAFE

        // mark time event 'te' as NOT linked
        te-&gt;m_flags &amp;= static_cast&lt;std::uint8_t&gt;(~QTE_FLAG_IS_LINKED);

        // do NOT advance the prev pointer
        QF_MEM_APP();
        QF_CRIT_EXIT(); // exit crit. section to reduce latency

        // NOTE: prevent merging critical sections
        // In some QF ports the critical section exit takes effect only
        // on the next machine instruction. If the next instruction is
        // another entry to a critical section, the critical section
        // might not be really exited, but rather the two adjacent
        // critical sections would be MERGED. The QF_CRIT_EXIT_NOP()
        // macro contains minimal code required to prevent such merging
        // of critical sections in QF ports, in which it can occur.
        QF_CRIT_EXIT_NOP();
    }
    else if (ctr == 1U) { // is time evt about to expire?
        QActive * const act = te-&gt;toActive();
        if (te-&gt;m_interval != 0U) { // periodic time evt?
            te-&gt;m_ctr = te-&gt;m_interval; // rearm the time event
#ifndef Q_UNSAFE
            te-&gt;m_ctr_dis = static_cast&lt;QTimeEvtCtr&gt;(~te-&gt;m_interval);
#endif // ndef Q_UNSAFE
            prev = te; // advance to this time event
        }
        else { // one-shot time event: automatically disarm
            te-&gt;m_ctr = 0U;
            prev-&gt;m_next = te-&gt;m_next;
#ifndef Q_UNSAFE
            te-&gt;m_ctr_dis =
                static_cast&lt;QTimeEvtCtr&gt;(~static_cast&lt;QTimeEvtCtr&gt;(0U));
            prev-&gt;m_next_dis =
                static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(te-&gt;m_next));
#endif // ndef Q_UNSAFE

            // mark time event 'te' as NOT linked
            te-&gt;m_flags &amp;=
                static_cast&lt;std::uint8_t&gt;(~QTE_FLAG_IS_LINKED);
            // do NOT advance the prev pointer

            QS_BEGIN_PRE(QS_QF_TIMEEVT_AUTO_DISARM, act-&gt;m_prio)
                QS_OBJ_PRE(te);       // this time event object
                QS_OBJ_PRE(act);      // the target AO
                QS_U8_PRE(tickRate);  // tick rate
            QS_END_PRE()
        }

        QS_BEGIN_PRE(QS_QF_TIMEEVT_POST, act-&gt;m_prio)
            QS_TIME_PRE();            // timestamp
            QS_OBJ_PRE(te);           // the time event object
            QS_SIG_PRE(te-&gt;sig);      // signal of this time event
            QS_OBJ_PRE(act);          // the target AO
            QS_U8_PRE(tickRate);      // tick rate
        QS_END_PRE()

#ifdef QXK_HPP_
        if (te-&gt;sig &lt; Q_USER_SIG) {
            QXThread::timeout_(act);
            QF_MEM_APP();
            QF_CRIT_EXIT();
        }
        else {
            QF_MEM_APP();
            QF_CRIT_EXIT(); // exit crit. section before posting

            // act-&gt;POST() asserts if the queue overflows
            act-&gt;POST(te, sender);
        }
#else
        QF_MEM_APP();
        QF_CRIT_EXIT(); // exit crit. section before posting

        // act-&gt;POST() asserts if the queue overflows
        act-&gt;POST(te, sender);
#endif
    }
    else { // time event keeps timing out
        --ctr; // decrement the tick counter
        te-&gt;m_ctr = ctr; // update the original
#ifndef Q_UNSAFE
        te-&gt;m_ctr_dis = static_cast&lt;QTimeEvtCtr&gt;(~ctr);
#endif // ndef Q_UNSAFE

        prev = te; // advance to this time event

        QF_MEM_APP();
        QF_CRIT_EXIT(); // exit crit. section to reduce latency

        // prevent merging critical sections, see NOTE above
        QF_CRIT_EXIT_NOP();
    }
    QF_CRIT_ENTRY(); // re-enter crit. section to continue the loop
    QF_MEM_SYS();
}

Q_ENSURE_INCRIT(890, lbound &gt; 0U);
QF_MEM_APP();
QF_CRIT_EXIT();</code>
   </operation>
   <!--${QF::QTimeEvt::tick1_}-->
   <operation name="tick1_?def Q_UTEST" type="void" visibility="0x00" properties="0x01">
    <!--${QF::QTimeEvt::tick1_::tickRate}-->
    <parameter name="tickRate" type="std::uint_fast8_t const"/>
    <!--${QF::QTimeEvt::tick1_::sender}-->
    <parameter name="sender" type="void const * const"/>
   </operation>
   <!--${QF::QTimeEvt::tickFromISR}-->
   <operation name="tickFromISR?def QF_ISR_API" type="void" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QF::QTimeEvt::tickFromISR::tickRate}-->
    <parameter name="tickRate" type="std::uint_fast8_t const"/>
    <!--${QF::QTimeEvt::tickFromISR::par}-->
    <parameter name="par" type="void *"/>
    <!--${QF::QTimeEvt::tickFromISR::sender}-->
    <parameter name="sender" type="void const *"/>
   </operation>
   <!--${QF::QTimeEvt::noActive}-->
   <operation name="noActive" type="bool" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QF::QTimeEvt::noActive::tickRate}-->
    <parameter name="tickRate" type="std::uint_fast8_t const"/>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
Q_REQUIRE_INCRIT(900, tickRate &lt; QF_MAX_TICK_RATE);
QF_CRIT_EXIT();

bool inactive;
if (timeEvtHead_[tickRate].m_next != nullptr) {
    inactive = false;
}
else if (timeEvtHead_[tickRate].m_act != nullptr) {
    inactive = false;
}
else {
    inactive = true;
}
return inactive;</code>
   </operation>
   <!--${QF::QTimeEvt::toActive}-->
   <operation name="toActive" type="QActive *" visibility="0x00" properties="0x02">
    <specifiers>noexcept</specifiers>
    <code>return static_cast&lt;QActive *&gt;(m_act);</code>
   </operation>
   <!--${QF::QTimeEvt::toTimeEvt}-->
   <operation name="toTimeEvt" type="QTimeEvt *" visibility="0x00" properties="0x02">
    <specifiers>noexcept</specifiers>
    <code>return static_cast&lt;QTimeEvt *&gt;(m_act);</code>
   </operation>
   <!--${QF::QTimeEvt::QTimeEvt}-->
   <operation name="QTimeEvt" type="" visibility="0x02" properties="0x00">
    <specifiers>noexcept</specifiers>
    <code> :  QEvt(0U),
    m_next(nullptr),
#ifndef Q_UNSAFE
    m_next_dis(static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(nullptr))),
#endif
    m_act(nullptr),
    m_ctr(0U),
#ifndef Q_UNSAFE
    m_ctr_dis(static_cast&lt;QTimeEvtCtr&gt;(~static_cast&lt;QTimeEvtCtr&gt;(0U))),
#endif
    m_interval(0U),
    m_tickRate(0U),
    m_flags(0U)</code>
   </operation>
   <!--${QF::QTimeEvt::QTimeEvt}-->
   <operation name="QTimeEvt" type="" visibility="0x02" properties="0x00">
    <specifiers>= delete</specifiers>
    <!--${QF::QTimeEvt::QTimeEvt::other}-->
    <parameter name="other" type="QTimeEvt const &amp;"/>
   </operation>
   <!--${QF::QTimeEvt::operator=}-->
   <operation name="operator=" type="QTimeEvt &amp;" visibility="0x02" properties="0x00">
    <specifiers>= delete</specifiers>
    <!--${QF::QTimeEvt::operator=::other}-->
    <parameter name="other" type="QTimeEvt const &amp;"/>
   </operation>
  </class>
  <!--${QF::QTicker}-->
  <class name="QTicker" superclass="QF::QActive">
   <!--${QF::QTicker::QTicker}-->
   <operation name="QTicker" type="explicit" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QTicker::QTicker::tickRate}-->
    <parameter name="tickRate" type="std::uint_fast8_t const"/>
    <code>: QActive(nullptr)

// reuse m_head for tick-rate
m_eQueue.m_head = static_cast&lt;QEQueueCtr&gt;(tickRate);
#ifndef Q_UNSAFE
m_eQueue.m_head_dis = static_cast&lt;QEQueueCtr&gt;(~tickRate);
#endif // ndef Q_UNSAFE</code>
   </operation>
   <!--${QF::QTicker::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x00">
    <specifiers>override</specifiers>
    <!--${QF::QTicker::init::e}-->
    <parameter name="e" type="void const * const"/>
    <!--${QF::QTicker::init::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>Q_UNUSED_PAR(e);
Q_UNUSED_PAR(qsId);

QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

m_eQueue.m_tail = 0U;
#ifndef Q_UNSAFE
m_eQueue.m_tail_dis = static_cast&lt;QEQueueCtr&gt;(~0U);
#endif // ndef Q_UNSAFE

QF_MEM_APP();
QF_CRIT_EXIT();</code>
   </operation>
   <!--${QF::QTicker::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x06">
    <specifiers>override</specifiers>
    <!--${QF::QTicker::init::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>this-&gt;init(nullptr, qsId);</code>
   </operation>
   <!--${QF::QTicker::dispatch}-->
   <operation name="dispatch" type="void" visibility="0x00" properties="0x00">
    <specifiers>override</specifiers>
    <!--${QF::QTicker::dispatch::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <!--${QF::QTicker::dispatch::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>Q_UNUSED_PAR(e);
Q_UNUSED_PAR(qsId);

QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

// get volatile into temporaries
QEQueueCtr nTicks = m_eQueue.m_tail;
QEQueueCtr const tickRate = m_eQueue.m_head;

#ifndef Q_UNSAFE
Q_REQUIRE_INCRIT(700, nTicks &gt; 0U);
Q_INVARIANT_INCRIT(701, nTicks
    == static_cast&lt;QEQueueCtr&gt;(~m_eQueue.m_tail_dis));
Q_INVARIANT_INCRIT(702, tickRate
    == static_cast&lt;QEQueueCtr&gt;(~m_eQueue.m_head_dis));
#endif // ndef Q_UNSAFE

m_eQueue.m_tail = 0U; // clear # ticks
#ifndef Q_UNSAFE
m_eQueue.m_tail_dis = static_cast&lt;QEQueueCtr&gt;(~0U);
#endif // ndef Q_UNSAFE

QF_MEM_APP();
QF_CRIT_EXIT();

for (; nTicks &gt; 0U; --nTicks) {
    QTimeEvt::tick(static_cast&lt;std::uint_fast8_t&gt;(tickRate),
                   this);
}</code>
   </operation>
   <!--${QF::QTicker::trig_}-->
   <operation name="trig_" type="void" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QTicker::trig_::sender}-->
    <parameter name="sender" type="void const * const"/>
    <code>#ifndef Q_SPY
Q_UNUSED_PAR(sender);
#endif

static QEvt const tickEvt(0U); // immutable event

QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

QEQueueCtr nTicks = m_eQueue.m_tail; // get volatile into temporary

if (m_eQueue.m_frontEvt == nullptr) {
#ifndef Q_UNSAFE
    Q_REQUIRE_INCRIT(800, nTicks == 0U);
    Q_REQUIRE_INCRIT(801, m_eQueue.m_nFree == 1U);
    Q_INVARIANT_INCRIT(802, m_eQueue.m_frontEvt_dis
        == static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(nullptr)));
    Q_INVARIANT_INCRIT(803,
        1U == static_cast&lt;QEQueueCtr&gt;(~m_eQueue.m_nFree_dis));
    Q_INVARIANT_INCRIT(804,
        0U == static_cast&lt;QEQueueCtr&gt;(~m_eQueue.m_tail_dis));
#endif // ndef Q_UNSAFE

    m_eQueue.m_frontEvt = &amp;tickEvt; // deliver event directly
    m_eQueue.m_nFree = 0U;
#ifndef Q_UNSAFE
    m_eQueue.m_frontEvt_dis =
        static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(&amp;tickEvt));
    m_eQueue.m_nFree_dis = static_cast&lt;QEQueueCtr&gt;(~0U);
#endif // ndef Q_UNSAFE

    QACTIVE_EQUEUE_SIGNAL_(this); // signal the event queue
}
else {
#ifndef Q_UNSAFE
    Q_REQUIRE_INCRIT(810, (nTicks &gt; 0U) &amp;&amp; (nTicks &lt; 0xFFU));
    Q_REQUIRE_INCRIT(811, m_eQueue.m_nFree == 0U);
    Q_INVARIANT_INCRIT(812, m_eQueue.m_frontEvt_dis
        == static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(&amp;tickEvt)));
    Q_INVARIANT_INCRIT(813,
        0U == static_cast&lt;QEQueueCtr&gt;(~m_eQueue.m_nFree_dis));
    Q_INVARIANT_INCRIT(814,
        nTicks == static_cast&lt;QEQueueCtr&gt;(~m_eQueue.m_tail_dis));
#endif // ndef Q_UNSAFE
}

++nTicks; // account for one more tick event

m_eQueue.m_tail = nTicks; // update the original
#ifndef Q_UNSAFE
m_eQueue.m_tail_dis = static_cast&lt;QEQueueCtr&gt;(~nTicks);
#endif // ndef Q_UNSAFE

QS_BEGIN_PRE(QS_QF_ACTIVE_POST, m_prio)
    QS_TIME_PRE();      // timestamp
    QS_OBJ_PRE(sender); // the sender object
    QS_SIG_PRE(0U);     // the signal of the event
    QS_OBJ_PRE(this);   // this active object
    QS_2U8_PRE(0U, 0U); // poolNum &amp; refCtr
    QS_EQC_PRE(0U);     // # free entries
    QS_EQC_PRE(0U);     // min # free entries
QS_END_PRE()

QF_MEM_APP();
QF_CRIT_EXIT();</code>
   </operation>
  </class>
  <!--${QF::QEQueue}-->
  <class name="QEQueue">
   <!--${QF::QEQueue::m_frontEvt}-->
   <attribute name="m_frontEvt" type="QEvt const * volatile" visibility="0x02" properties="0x00"/>
   <!--${QF::QEQueue::m_ring}-->
   <attribute name="m_ring" type="QEvt const * *" visibility="0x02" properties="0x00"/>
   <!--${QF::QEQueue::m_end}-->
   <attribute name="m_end" type="QEQueueCtr" visibility="0x02" properties="0x00"/>
   <!--${QF::QEQueue::m_head}-->
   <attribute name="m_head" type="QEQueueCtr volatile" visibility="0x02" properties="0x00"/>
   <!--${QF::QEQueue::m_tail}-->
   <attribute name="m_tail" type="QEQueueCtr volatile" visibility="0x02" properties="0x00"/>
   <!--${QF::QEQueue::m_nFree}-->
   <attribute name="m_nFree" type="QEQueueCtr volatile" visibility="0x02" properties="0x00"/>
   <!--${QF::QEQueue::m_frontEvt_dis}-->
   <attribute name="m_frontEvt_dis?ndef Q_UNSAFE" type="std::uintptr_t" visibility="0x02" properties="0x00"/>
   <!--${QF::QEQueue::m_head_dis}-->
   <attribute name="m_head_dis?ndef Q_UNSAFE" type="QEQueueCtr" visibility="0x02" properties="0x00"/>
   <!--${QF::QEQueue::m_tail_dis}-->
   <attribute name="m_tail_dis?ndef Q_UNSAFE" type="QEQueueCtr" visibility="0x02" properties="0x00"/>
   <!--${QF::QEQueue::m_nFree_dis}-->
   <attribute name="m_nFree_dis?ndef Q_UNSAFE" type="QEQueueCtr" visibility="0x02" properties="0x00"/>
   <!--${QF::QEQueue::m_nMin}-->
   <attribute name="m_nMin" type="QEQueueCtr" visibility="0x02" properties="0x00"/>
   <!--${QF::QEQueue::QActive}-->
   <attribute name="QActive" type="friend class" visibility="0x02" properties="0x00">
    <documentation>// friends...</documentation>
   </attribute>
   <!--${QF::QEQueue::QTicker}-->
   <attribute name="QTicker" type="friend class" visibility="0x02" properties="0x00"/>
   <!--${QF::QEQueue::QXMutex}-->
   <attribute name="QXMutex" type="friend class" visibility="0x02" properties="0x00"/>
   <!--${QF::QEQueue::QXThread}-->
   <attribute name="QXThread" type="friend class" visibility="0x02" properties="0x00"/>
   <!--${QF::QEQueue::QEQueue}-->
   <operation name="QEQueue" type="" visibility="0x00" properties="0x02">
    <specifiers>noexcept</specifiers>
    <code>  : m_frontEvt(nullptr),
    m_ring(nullptr),
    m_end(0U),
    m_head(0U),
    m_tail(0U),
    m_nFree(0U),
#ifndef Q_UNSAFE
    m_frontEvt_dis(static_cast&lt;std::uintptr_t&gt;(~0U)),
    m_head_dis(static_cast&lt;QEQueueCtr&gt;(~0U)),
    m_tail_dis(static_cast&lt;QEQueueCtr&gt;(~0U)),
    m_nFree_dis(static_cast&lt;QEQueueCtr&gt;(~0U)),
#endif
    m_nMin(0U)</code>
   </operation>
   <!--${QF::QEQueue::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QEQueue::init::qSto[]}-->
    <parameter name="qSto[]" type="QEvt const *"/>
    <!--${QF::QEQueue::init::qLen}-->
    <parameter name="qLen" type="std::uint_fast16_t const"/>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

#if (QF_EQUEUE_CTR_SIZE == 1U)
Q_REQUIRE_INCRIT(100, qLen &lt; 0xFFU);
#endif

m_frontEvt = nullptr; // no events in the queue
m_ring     = &amp;qSto[0];
m_end      = static_cast&lt;QEQueueCtr&gt;(qLen);
if (qLen &gt; 0U) {
    m_head = 0U;
    m_tail = 0U;
}
m_nFree    = static_cast&lt;QEQueueCtr&gt;(qLen + 1U); //+1 for frontEvt
m_nMin     = m_nFree;

#ifndef Q_UNSAFE
m_frontEvt_dis = static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(m_frontEvt));
m_head_dis  = static_cast&lt;QEQueueCtr&gt;(~m_head);
m_tail_dis  = static_cast&lt;QEQueueCtr&gt;(~m_tail);
m_nFree_dis = static_cast&lt;QEQueueCtr&gt;(~m_nFree);
#endif

QF_MEM_APP();
QF_CRIT_EXIT();</code>
   </operation>
   <!--${QF::QEQueue::post}-->
   <operation name="post" type="bool" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QEQueue::post::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <!--${QF::QEQueue::post::margin}-->
    <parameter name="margin" type="std::uint_fast16_t const"/>
    <!--${QF::QEQueue::post::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>#ifndef Q_SPY
Q_UNUSED_PAR(qsId);
#endif

QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_REQUIRE_INCRIT(200, e != nullptr);
Q_INVARIANT_INCRIT(201, e-&gt;verify_());

QEQueueCtr tmp = m_nFree; // get volatile into temporary
#ifndef Q_UNSAFE
QEQueueCtr dis = static_cast&lt;QEQueueCtr&gt;(~m_nFree_dis);
Q_INVARIANT_INCRIT(201, tmp == dis);
#endif // ndef Q_UNSAFE

// test-probe#1 for faking queue overflow
QS_TEST_PROBE_DEF(&amp;QEQueue::post)
QS_TEST_PROBE_ID(1,
    tmp = 0U; // fake no free events
)

// required margin available?
bool status;
if (((margin == QF::NO_MARGIN) &amp;&amp; (tmp &gt; 0U))
    || (tmp &gt; static_cast&lt;QEQueueCtr&gt;(margin)))
{
    // is it a mutable event?
    if (e-&gt;getPoolNum_() != 0U) {
        QEvt_refCtr_inc_(e); // increment the reference counter
    }

    --tmp; // one free entry just used up

    m_nFree = tmp; // update the original
#ifndef Q_UNSAFE
    m_nFree_dis = static_cast&lt;QEQueueCtr&gt;(~tmp);
#endif // ndef Q_UNSAFE

    if (m_nMin &gt; tmp) {
        m_nMin = tmp; // update minimum so far
    }

    QS_BEGIN_PRE(QS_QF_EQUEUE_POST, qsId)
        QS_TIME_PRE();        // timestamp
        QS_SIG_PRE(e-&gt;sig);   // the signal of the event
        QS_OBJ_PRE(this);     // this queue object
        QS_2U8_PRE(e-&gt;getPoolNum_(), e-&gt;refCtr_);
        QS_EQC_PRE(tmp);      // # free entries
        QS_EQC_PRE(m_nMin);   // min # free entries
    QS_END_PRE()

    if (m_frontEvt == nullptr) { // is the queue empty?
        m_frontEvt = e; // deliver event directly
#ifndef Q_UNSAFE
        Q_INVARIANT_INCRIT(211, m_frontEvt_dis
            == static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(nullptr)));
        m_frontEvt_dis = static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(e));
#endif // ndef Q_UNSAFE
    }
    else { // queue was not empty, insert event into the ring-buffer
        tmp = m_head; // get volatile into temporary
#ifndef Q_UNSAFE
        dis = static_cast&lt;QEQueueCtr&gt;(~m_head_dis);
        Q_INVARIANT_INCRIT(212, tmp == dis);
#endif // ndef Q_UNSAFE
        m_ring[tmp] = e; // insert e into buffer

        if (tmp == 0U) { // need to wrap the head?
            tmp = m_end;
        }
        --tmp; // advance head (counter-clockwise)

        m_head = tmp; // update the original
#ifndef Q_UNSAFE
        m_head_dis = static_cast&lt;QEQueueCtr&gt;(~tmp);
#endif // ndef Q_UNSAFE
    }
    status = true; // event posted successfully
}
else { // event cannot be posted
    // dropping events must be acceptable
    Q_ASSERT_INCRIT(210, margin != QF::NO_MARGIN);

    QS_BEGIN_PRE(QS_QF_EQUEUE_POST_ATTEMPT, qsId)
        QS_TIME_PRE();        // timestamp
        QS_SIG_PRE(e-&gt;sig);   // the signal of this event
        QS_OBJ_PRE(this);     // this queue object
        QS_2U8_PRE(e-&gt;getPoolNum_(), e-&gt;refCtr_);
        QS_EQC_PRE(tmp);      // # free entries
        QS_EQC_PRE(margin);   // margin requested
    QS_END_PRE()

    status = false; // event not posted
}

QF_MEM_APP();
QF_CRIT_EXIT();

return status;</code>
   </operation>
   <!--${QF::QEQueue::postLIFO}-->
   <operation name="postLIFO" type="void" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QEQueue::postLIFO::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <!--${QF::QEQueue::postLIFO::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>#ifndef Q_SPY
Q_UNUSED_PAR(qsId);
#endif

QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_REQUIRE_INCRIT(300, e != nullptr);
Q_INVARIANT_INCRIT(301, e-&gt;verify_());

QEQueueCtr tmp = m_nFree; // get volatile into temporary
#ifndef Q_UNSAFE
QEQueueCtr dis = static_cast&lt;QEQueueCtr&gt;(~m_nFree_dis);
Q_INVARIANT_INCRIT(301, tmp == dis);
#endif // ndef Q_UNSAFE

// test-probe#1 for faking queue overflow
QS_TEST_PROBE_DEF(&amp;QEQueue::postLIFO)
QS_TEST_PROBE_ID(1,
    tmp = 0U; // fake no free events
)

// must be able to LIFO-post the event
Q_REQUIRE_INCRIT(310, tmp != 0U);

if (e-&gt;getPoolNum_() != 0U) { // is it a mutable event?
    QEvt_refCtr_inc_(e); // increment the reference counter
}

--tmp; // one free entry just used up

m_nFree = tmp; // update the original
#ifndef Q_UNSAFE
m_nFree_dis = static_cast&lt;QEQueueCtr&gt;(~tmp);
#endif // ndef Q_UNSAFE

if (m_nMin &gt; tmp) {
    m_nMin = tmp; // update minimum so far
}

QS_BEGIN_PRE(QS_QF_EQUEUE_POST_LIFO, qsId)
    QS_TIME_PRE();       // timestamp
    QS_SIG_PRE(e-&gt;sig);  // the signal of this event
    QS_OBJ_PRE(this);    // this queue object
    QS_2U8_PRE(e-&gt;getPoolNum_(), e-&gt;refCtr_);
    QS_EQC_PRE(tmp);     // # free entries
    QS_EQC_PRE(m_nMin);  // min # free entries
QS_END_PRE()

QEvt const * const frontEvt = m_frontEvt; // read into temporary
m_frontEvt = e; // deliver the event directly to the front
#ifndef Q_UNSAFE
m_frontEvt_dis = static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(e));
#endif // ndef Q_UNSAFE

if (frontEvt != nullptr) { // was the queue NOT empty?
    tmp = m_tail; // get volatile into temporary;
#ifndef Q_UNSAFE
    dis = static_cast&lt;QEQueueCtr&gt;(~m_tail_dis);
    Q_INVARIANT_INCRIT(311, tmp == dis);
#endif // ndef Q_UNSAFE
    ++tmp;
    if (tmp == m_end) { // need to wrap the tail?
        tmp = 0U; // wrap around
    }
    m_tail = tmp;
#ifndef Q_UNSAFE
    m_tail_dis = static_cast&lt;QEQueueCtr&gt;(~tmp);
#endif
    m_ring[tmp] = frontEvt;
}

QF_MEM_APP();
QF_CRIT_EXIT();</code>
   </operation>
   <!--${QF::QEQueue::get}-->
   <operation name="get" type="QEvt const *" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QEQueue::get::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>#ifndef Q_SPY
Q_UNUSED_PAR(qsId);
#endif

QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

QEvt const * const e = m_frontEvt; // always remove evt from the front
#ifndef Q_UNSAFE
Q_INVARIANT_INCRIT(411, Q_PTR2UINT_CAST_(e)
                        == static_cast&lt;std::uintptr_t&gt;(~m_frontEvt_dis));
#endif // ndef Q_UNSAFE

if (e != nullptr) { // was the queue not empty?
    QEQueueCtr tmp = m_nFree; // get volatile into temporary
#ifndef Q_UNSAFE
    QEQueueCtr const dis = static_cast&lt;QEQueueCtr&gt;(~m_nFree_dis);
    Q_INVARIANT_INCRIT(412, tmp == dis);
#endif // ndef Q_UNSAFE

    ++tmp; // one more free event in the queue

    m_nFree = tmp; // update the # free
#ifndef Q_UNSAFE
    m_nFree_dis = static_cast&lt;QEQueueCtr&gt;(~tmp);
#endif // ndef Q_UNSAFE

    // any events in the ring buffer?
    if (tmp &lt;= m_end) {

        QS_BEGIN_PRE(QS_QF_EQUEUE_GET, qsId)
            QS_TIME_PRE();      // timestamp
            QS_SIG_PRE(e-&gt;sig); // the signal of this event
            QS_OBJ_PRE(this);   // this queue object
            QS_2U8_PRE(e-&gt;getPoolNum_(), e-&gt;refCtr_);
            QS_EQC_PRE(tmp);    // # free entries
        QS_END_PRE()

        tmp = m_tail; // get volatile into temporary
        QEvt const * const frontEvt = m_ring[tmp];
#ifndef Q_UNSAFE
        Q_ASSERT_INCRIT(421, frontEvt != nullptr);
        m_frontEvt_dis =
            static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(frontEvt));
#endif // ndef Q_UNSAFE
        m_frontEvt = frontEvt; // update the original

        if (tmp == 0U) { // need to wrap the tail?
            tmp = m_end;
        }
        --tmp; // advance the tail (counter-clockwise)
        m_tail = tmp; // update the original
#ifndef Q_UNSAFE
        m_tail_dis = static_cast&lt;QEQueueCtr&gt;(~tmp);
#endif // ndef Q_UNSAFE
    }
    else {
        m_frontEvt = nullptr; // queue becomes empty
#ifndef Q_UNSAFE
        m_frontEvt_dis =
            static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(nullptr));
#endif // ndef Q_UNSAFE

        // all entries in the queue must be free (+1 for frontEvt)
        Q_INVARIANT_INCRIT(440, tmp == (m_end + 1U));

        QS_BEGIN_PRE(QS_QF_EQUEUE_GET_LAST, qsId)
            QS_TIME_PRE();      // timestamp
            QS_SIG_PRE(e-&gt;sig); // the signal of this event
            QS_OBJ_PRE(this);   // this queue object
            QS_2U8_PRE(e-&gt;getPoolNum_(), e-&gt;refCtr_);
        QS_END_PRE()
    }
}

QF_MEM_APP();
QF_CRIT_EXIT();

return e;</code>
   </operation>
   <!--${QF::QEQueue::getNFree}-->
   <operation name="getNFree" type="QEQueueCtr" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>return m_nFree;</code>
   </operation>
   <!--${QF::QEQueue::getNMin}-->
   <operation name="getNMin" type="QEQueueCtr" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>#ifndef Q_UNSAFE
return m_nMin;
#else
return 0U;
#endif</code>
   </operation>
   <!--${QF::QEQueue::isEmpty}-->
   <operation name="isEmpty" type="bool" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>return m_frontEvt == nullptr;</code>
   </operation>
   <!--${QF::QEQueue::QEQueue}-->
   <operation name="QEQueue" type="" visibility="0x02" properties="0x00">
    <specifiers>= delete</specifiers>
    <!--${QF::QEQueue::QEQueue::other}-->
    <parameter name="other" type="QEQueue const &amp;"/>
   </operation>
   <!--${QF::QEQueue::operator=}-->
   <operation name="operator=" type="QEQueue &amp;" visibility="0x02" properties="0x00">
    <specifiers>= delete</specifiers>
    <!--${QF::QEQueue::operator=::other}-->
    <parameter name="other" type="QEQueue const &amp;"/>
   </operation>
  </class>
  <!--${QF::QFreeBlock}-->
  <class name="QFreeBlock">
   <!--${QF::QFreeBlock::m_next}-->
   <attribute name="m_next" type="QFreeBlock *" visibility="0x02" properties="0x00"/>
   <!--${QF::QFreeBlock::m_next_dis}-->
   <attribute name="m_next_dis?ndef Q_UNSAFE" type="std::uintptr_t" visibility="0x02" properties="0x00"/>
   <!--${QF::QFreeBlock::QMPool}-->
   <attribute name="QMPool" type="friend class" visibility="0x02" properties="0x00"/>
  </class>
  <!--${QF::QMPool}-->
  <class name="QMPool">
   <!--${QF::QMPool::m_start}-->
   <attribute name="m_start" type="QFreeBlock *" visibility="0x02" properties="0x00"/>
   <!--${QF::QMPool::m_end}-->
   <attribute name="m_end" type="QFreeBlock *" visibility="0x02" properties="0x00"/>
   <!--${QF::QMPool::m_free_head}-->
   <attribute name="m_free_head" type="QFreeBlock * volatile" visibility="0x02" properties="0x00"/>
   <!--${QF::QMPool::m_blockSize}-->
   <attribute name="m_blockSize" type="QMPoolSize" visibility="0x02" properties="0x00"/>
   <!--${QF::QMPool::m_nTot}-->
   <attribute name="m_nTot" type="QMPoolCtr" visibility="0x02" properties="0x00"/>
   <!--${QF::QMPool::m_nFree}-->
   <attribute name="m_nFree" type="QMPoolCtr volatile" visibility="0x02" properties="0x00"/>
   <!--${QF::QMPool::m_nMin}-->
   <attribute name="m_nMin?ndef Q_UNSAFE" type="QMPoolCtr" visibility="0x02" properties="0x00"/>
   <!--${QF::QMPool::m_free_head_dis}-->
   <attribute name="m_free_head_dis?ndef Q_UNSAFE" type="std::uintptr_t" visibility="0x02" properties="0x00"/>
   <!--${QF::QMPool::m_nFree_dis}-->
   <attribute name="m_nFree_dis?ndef Q_UNSAFE" type="QMPoolCtr" visibility="0x02" properties="0x00"/>
   <!--${QF::QMPool::QMPool}-->
   <operation name="QMPool" type="" visibility="0x00" properties="0x02">
    <code>  : m_start(nullptr),
    m_end(nullptr),
    m_free_head(nullptr),
    m_blockSize(0U),
    m_nTot(0U),
    m_nFree(0U)
#ifndef Q_UNSAFE
   ,m_nMin(0U),
    m_free_head_dis(static_cast&lt;std::uintptr_t&gt;(~0U)),
    m_nFree_dis(static_cast&lt;QEQueueCtr&gt;(~0U))
#endif</code>
   </operation>
   <!--${QF::QMPool::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QMPool::init::poolSto}-->
    <parameter name="poolSto" type="void * const"/>
    <!--${QF::QMPool::init::poolSize}-->
    <parameter name="poolSize" type="std::uint_fast32_t const"/>
    <!--${QF::QMPool::init::blockSize}-->
    <parameter name="blockSize" type="std::uint_fast16_t const"/>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_REQUIRE_INCRIT(100, poolSto != nullptr);
Q_REQUIRE_INCRIT(101,
    poolSize &gt;= static_cast&lt;std::uint_fast32_t&gt;(sizeof(QFreeBlock)));
Q_REQUIRE_INCRIT(102,
    static_cast&lt;std::uint_fast16_t&gt;(blockSize + sizeof(QFreeBlock))
        &gt; blockSize);

m_free_head = static_cast&lt;QFreeBlock *&gt;(poolSto);

// find # free blocks in a memory block, NO DIVISION
m_blockSize = static_cast&lt;QMPoolSize&gt;(2U * sizeof(void *));
std::uint_fast16_t nblocks = 1U;
while (m_blockSize &lt; static_cast&lt;QMPoolSize&gt;(blockSize)) {
    m_blockSize += static_cast&lt;QMPoolSize&gt;(sizeof(QFreeBlock));
    ++nblocks;
}

// the pool buffer must fit at least one rounded-up block
Q_ASSERT_INCRIT(110, poolSize &gt;= m_blockSize);

// start at the head of the free list
QFreeBlock *fb = m_free_head;
std::uint32_t nTot = 1U; // the last block already in the list

// chain all blocks together in a free-list...
for (std::uint_fast32_t size = poolSize - m_blockSize;
     size &gt;= static_cast&lt;std::uint_fast32_t&gt;(m_blockSize);
     size -= static_cast&lt;std::uint_fast32_t&gt;(m_blockSize))
{
    fb-&gt;m_next = &amp;fb[nblocks]; // point next link to next block
#ifndef Q_UNSAFE
    fb-&gt;m_next_dis = ~Q_PTR2UINT_CAST_(fb-&gt;m_next);
#endif
    fb = fb-&gt;m_next; // advance to the next block
    ++nTot;          // one more free block in the pool
}

// dynamic range check
#if (QF_MPOOL_CTR_SIZE == 1U)
Q_ENSURE_INCRIT(190, nTot &lt; 0xFFU);
#elif (QF_MPOOL_CTR_SIZE == 2U)
Q_ENSURE_INCRIT(190, nTot &lt; 0xFFFFU);
#endif

fb-&gt;m_next  = nullptr; // the last link points to NULL

m_nTot  = static_cast&lt;QMPoolCtr&gt;(nTot);
m_nFree = m_nTot;  // all blocks are free
m_start = static_cast&lt;QFreeBlock *&gt;(poolSto); // original start
m_end   = fb;      // the last block in this pool

#ifndef Q_UNSAFE
m_free_head_dis =
    static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(m_free_head));
m_nFree_dis    = static_cast&lt;QMPoolCtr&gt;(~m_nFree);
m_nMin         = m_nTot;  // the minimum # free blocks
fb-&gt;m_next_dis = ~Q_PTR2UINT_CAST_(fb-&gt;m_next);
#endif

QF_MEM_APP();
QF_CRIT_EXIT();</code>
   </operation>
   <!--${QF::QMPool::get}-->
   <operation name="get" type="void *" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QMPool::get::margin}-->
    <parameter name="margin" type="std::uint_fast16_t const"/>
    <!--${QF::QMPool::get::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>#ifndef Q_SPY
Q_UNUSED_PAR(qsId);
#endif

QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

// get volatile into temporaries
QFreeBlock *fb = m_free_head;
QMPoolCtr nFree = m_nFree;

#ifndef Q_UNSAFE
Q_INVARIANT_INCRIT(301, Q_PTR2UINT_CAST_(fb)
    == static_cast&lt;std::uintptr_t&gt;(~m_free_head_dis));
Q_INVARIANT_INCRIT(302, nFree == static_cast&lt;QMPoolCtr&gt;(~m_nFree_dis));
#endif // ndef Q_UNSAFE

// have more free blocks than the requested margin?
if (nFree &gt; static_cast&lt;QMPoolCtr&gt;(margin)) {
    Q_ASSERT_INCRIT(310, fb != nullptr);

    QFreeBlock * const fb_next = fb-&gt;m_next;

#ifndef Q_UNSAFE
    // the free block must have integrity (duplicate inverse storage)
    Q_INVARIANT_INCRIT(311, Q_PTR2UINT_CAST_(fb_next)
        == static_cast&lt;std::uintptr_t&gt;(~fb-&gt;m_next_dis));
#endif // ndef Q_UNSAFE

    --nFree; // one less free block
    if (nFree == 0U) { // is the pool becoming empty?
        // pool is becoming empty, so the next free block must be NULL
        Q_ASSERT_INCRIT(320, fb_next == nullptr);

        m_nFree = 0U;
#ifndef Q_UNSAFE
        m_nFree_dis = static_cast&lt;QMPoolCtr&gt;(~m_nFree);
        m_nMin = 0U; // remember that the pool got empty
#endif // ndef Q_UNSAFE
    }
    else {
        m_nFree = nFree; // update the original
#ifndef Q_UNSAFE
        m_nFree_dis = static_cast&lt;QMPoolCtr&gt;(~nFree);

        // The pool is not empty, so the next free-block pointer
        // must be in range.
        Q_INVARIANT_INCRIT(330,
            QF_PTR_RANGE_(fb_next, m_start, m_end));

        // is the # free blocks the new minimum so far?
        if (m_nMin &gt; nFree) {
            m_nMin = nFree; // remember the minimum so far
        }
#endif // ndef Q_UNSAFE
    }

    m_free_head = fb_next; // set the head to the next free block
#ifndef Q_UNSAFE
    m_free_head_dis =
        static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(fb_next));
#endif // ndef Q_UNSAFE

    QS_BEGIN_PRE(QS_QF_MPOOL_GET, qsId)
        QS_TIME_PRE();         // timestamp
        QS_OBJ_PRE(this);      // this memory pool
        QS_MPC_PRE(nFree);     // # of free blocks in the pool
#ifndef Q_UNSAFE
        QS_MPC_PRE(m_nMin);    // min # free blocks ever in the pool
#else
        QS_MPC_PRE(0U);        // min # free blocks (not available)
#endif // ndef Q_UNSAFE
    QS_END_PRE()
}
else { // don't have enough free blocks at this point
    fb = nullptr;

    QS_BEGIN_PRE(QS_QF_MPOOL_GET_ATTEMPT, qsId)
        QS_TIME_PRE();         // timestamp
        QS_OBJ_PRE(this);      // this memory pool
        QS_MPC_PRE(nFree);     // # of free blocks in the pool
        QS_MPC_PRE(margin);    // the requested margin
    QS_END_PRE()
}

QF_MEM_APP();
QF_CRIT_EXIT();

return fb; // return the block or nullptr to the caller</code>
   </operation>
   <!--${QF::QMPool::put}-->
   <operation name="put" type="void" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QMPool::put::block}-->
    <parameter name="block" type="void * const"/>
    <!--${QF::QMPool::put::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>#ifndef Q_SPY
Q_UNUSED_PAR(qsId);
#endif

QFreeBlock * const fb = static_cast&lt;QFreeBlock *&gt;(block);

QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

// get volatile into temporaries
QFreeBlock * const free_head = m_free_head;
QMPoolCtr nFree = m_nFree;

#ifndef Q_UNSAFE
Q_INVARIANT_INCRIT(401, Q_PTR2UINT_CAST_(free_head)
    == static_cast&lt;std::uintptr_t&gt;(~m_free_head_dis));
Q_INVARIANT_INCRIT(402, nFree == static_cast&lt;QMPoolCtr&gt;(~m_nFree_dis));

Q_REQUIRE_INCRIT(410, nFree &lt; m_nTot);
Q_REQUIRE_INCRIT(411, QF_PTR_RANGE_(fb, m_start, m_end));

// the block must not be in the pool already
Q_REQUIRE_INCRIT(412, Q_PTR2UINT_CAST_(fb-&gt;m_next)
    != static_cast&lt;std::uintptr_t&gt;(~fb-&gt;m_next_dis));
#endif // ndef Q_UNSAFE

++nFree; // one more free block in this pool

m_free_head = fb; // set as new head of the free list
m_nFree     = nFree;
fb-&gt;m_next  = free_head; // link into the list
#ifndef Q_UNSAFE
m_free_head_dis = static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(fb));
m_nFree_dis     = static_cast&lt;QMPoolCtr&gt;(~nFree);
fb-&gt;m_next_dis  = static_cast&lt;std::uintptr_t&gt;(~Q_PTR2UINT_CAST_(free_head));
#endif

QS_BEGIN_PRE(QS_QF_MPOOL_PUT, qsId)
    QS_TIME_PRE();         // timestamp
    QS_OBJ_PRE(this);      // this memory pool
    QS_MPC_PRE(nFree);     // the # free blocks in the pool
QS_END_PRE()

QF_MEM_APP();
QF_CRIT_EXIT();</code>
   </operation>
   <!--${QF::QMPool::getBlockSize}-->
   <operation name="getBlockSize" type="QMPoolSize" visibility="0x00" properties="0x00">
    <specifiers>const noexcept</specifiers>
    <code>return m_blockSize;</code>
   </operation>
   <!--${QF::QMPool::getNMin}-->
   <operation name="getNMin" type="QMPoolCtr" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>#ifndef Q_UNSAFE
return m_nMin;
#else
return 0U;
#endif</code>
   </operation>
   <!--${QF::QMPool::getNFree}-->
   <operation name="getNFree" type="QMPoolCtr" visibility="0x00" properties="0x02">
    <specifiers>const noexcept</specifiers>
    <code>return m_nFree;</code>
   </operation>
   <!--${QF::QMPool::QMPool}-->
   <operation name="QMPool" type="" visibility="0x02" properties="0x00">
    <specifiers>= delete</specifiers>
    <!--${QF::QMPool::QMPool::other}-->
    <parameter name="other" type="QEQueue const &amp;"/>
   </operation>
   <!--${QF::QMPool::operator=}-->
   <operation name="operator=" type="QMPool &amp;" visibility="0x02" properties="0x00">
    <specifiers>= delete</specifiers>
    <!--${QF::QMPool::operator=::other}-->
    <parameter name="other" type="QMPool const &amp;"/>
   </operation>
   <!--${QF::QMPool::getFromISR}-->
   <operation name="getFromISR?def QF_ISR_API" type="void *" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QMPool::getFromISR::margin}-->
    <parameter name="margin" type="std::uint_fast16_t const"/>
    <!--${QF::QMPool::getFromISR::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
   </operation>
   <!--${QF::QMPool::putFromISR}-->
   <operation name="putFromISR?def QF_ISR_API" type="void" visibility="0x00" properties="0x00">
    <specifiers>noexcept</specifiers>
    <!--${QF::QMPool::putFromISR::b}-->
    <parameter name="b" type="void * const"/>
    <!--${QF::QMPool::putFromISR::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
   </operation>
  </class>
  <!--${QF::QF-pkg}-->
  <package name="QF-pkg" stereotype="0x02" namespace="QF::">
   <!--${QF::QF-pkg::Attr}-->
   <class name="Attr">
    <!--${QF::QF-pkg::Attr::ePool_[QF_MAX_EPOOL]}-->
    <attribute name="ePool_[QF_MAX_EPOOL]? (QF_MAX_EPOOL &gt; 0U)" type="QF_EPOOL_TYPE_" visibility="0x00" properties="0x00"/>
    <!--${QF::QF-pkg::Attr::maxPool_}-->
    <attribute name="maxPool_? (QF_MAX_EPOOL &gt; 0U)" type="std::uint_fast8_t" visibility="0x00" properties="0x00"/>
    <!--${QF::QF-pkg::Attr::dummy}-->
    <attribute name="dummy? (QF_MAX_EPOOL == 0U)" type="std::uint8_t" visibility="0x00" properties="0x00"/>
   </class>
   <!--${QF::QF-pkg::priv_}-->
   <attribute name="priv_" type="QF::Attr" visibility="0x00" properties="0x00"/>
   <!--${QF::QF-pkg::bzero_}-->
   <operation name="bzero_" type="void" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QF::QF-pkg::bzero_::start}-->
    <parameter name="start" type="void * const"/>
    <!--${QF::QF-pkg::bzero_::len}-->
    <parameter name="len" type="std::uint_fast16_t const"/>
    <code>std::uint8_t *ptr = static_cast&lt;std::uint8_t *&gt;(start);
for (std::uint_fast16_t n = len; n &gt; 0U; --n) {
    *ptr = 0U;
    ++ptr;
}</code>
   </operation>
  </package>
  <!--${QF::QF-base}-->
  <package name="QF-base" stereotype="0x02" namespace="QF::">
   <!--${QF::QF-base::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x01"/>
   <!--${QF::QF-base::stop}-->
   <operation name="stop" type="void" visibility="0x00" properties="0x01"/>
   <!--${QF::QF-base::run}-->
   <operation name="run" type="int_t" visibility="0x00" properties="0x01"/>
   <!--${QF::QF-base::onStartup}-->
   <operation name="onStartup" type="void" visibility="0x00" properties="0x01"/>
   <!--${QF::QF-base::onCleanup}-->
   <operation name="onCleanup" type="void" visibility="0x00" properties="0x01"/>
   <!--${QF::QF-base::psInit}-->
   <operation name="psInit" type="void" visibility="0x00" properties="0x03">
    <specifiers>noexcept</specifiers>
    <documentation>//! @deprecated</documentation>
    <!--${QF::QF-base::psInit::subscrSto}-->
    <parameter name="subscrSto" type="QSubscrList * const"/>
    <!--${QF::QF-base::psInit::maxSignal}-->
    <parameter name="maxSignal" type="enum_t const"/>
    <code>QActive::psInit(subscrSto, maxSignal);</code>
   </operation>
   <!--${QF::QF-base::publish_}-->
   <operation name="publish_" type="void" visibility="0x00" properties="0x03">
    <specifiers>noexcept</specifiers>
    <documentation>//! @deprecated</documentation>
    <!--${QF::QF-base::publish_::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <!--${QF::QF-base::publish_::sender}-->
    <parameter name="sender" type="void const * const"/>
    <!--${QF::QF-base::publish_::qsId}-->
    <parameter name="qsId" type="std::uint_fast8_t const"/>
    <code>QActive::publish_(e, sender, qsId);</code>
   </operation>
   <!--${QF::QF-base::tick}-->
   <operation name="tick" type="void" visibility="0x00" properties="0x03">
    <specifiers>noexcept</specifiers>
    <documentation>//! @deprecated</documentation>
    <!--${QF::QF-base::tick::tickRate}-->
    <parameter name="tickRate" type="std::uint_fast8_t const"/>
    <!--${QF::QF-base::tick::sender}-->
    <parameter name="sender" type="void const * const"/>
    <code>QTimeEvt::tick(tickRate, sender);</code>
   </operation>
   <!--${QF::QF-base::getQueueMin}-->
   <operation name="getQueueMin" type="std::uint_fast16_t" visibility="0x00" properties="0x03">
    <specifiers>noexcept</specifiers>
    <documentation>//! @deprecated</documentation>
    <!--${QF::QF-base::getQueueMin::prio}-->
    <parameter name="prio" type="std::uint_fast8_t const"/>
    <code>return QActive::getQueueMin(prio);</code>
   </operation>
   <!--${QF::QF-base::NO_MARGIN}-->
   <attribute name="NO_MARGIN" type="constexpr std::uint_fast16_t" visibility="0x04" properties="0x00">
    <code>{0xFFFFU};</code>
   </attribute>
  </package>
  <!--${QF::QF-dyn}-->
  <package name="QF-dyn" stereotype="0x02" namespace="QF::">
   <!--${QF::QF-dyn::poolInit}-->
   <operation name="poolInit" type="void" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QF::QF-dyn::poolInit::poolSto}-->
    <parameter name="poolSto" type="void * const"/>
    <!--${QF::QF-dyn::poolInit::poolSize}-->
    <parameter name="poolSize" type="std::uint_fast32_t const"/>
    <!--${QF::QF-dyn::poolInit::evtSize}-->
    <parameter name="evtSize" type="std::uint_fast16_t const"/>
    <code>std::uint_fast8_t const poolNum = priv_.maxPool_;

// see precondition{qf_dyn,200} and precondition{qf_dyn,201}
QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_REQUIRE_INCRIT(200, poolNum &lt; QF_MAX_EPOOL);
if (poolNum &gt; 0U) {
    Q_REQUIRE_INCRIT(201,
        QF_EPOOL_EVENT_SIZE_(priv_.ePool_[poolNum - 1U]) &lt; evtSize);
}
priv_.maxPool_ = poolNum + 1U; // one more pool

QF_MEM_APP();
QF_CRIT_EXIT();

// perform the port-dependent initialization of the event-pool
QF_EPOOL_INIT_(priv_.ePool_[poolNum], poolSto, poolSize, evtSize);

#ifdef Q_SPY
// generate the object-dictionary entry for the initialized pool
{
    std::uint8_t obj_name[9] = &quot;EvtPool?&quot;;
    obj_name[7] = static_cast&lt;std::uint8_t&gt;(
        static_cast&lt;std::uint8_t&gt;('0')
        + static_cast&lt;std::uint8_t&gt;(poolNum + 1U));
    QS::obj_dict_pre_(&amp;priv_.ePool_[poolNum],
                      reinterpret_cast&lt;char *&gt;(&amp;obj_name[0]));
}
#endif // Q_SPY</code>
   </operation>
   <!--${QF::QF-dyn::poolGetMaxBlockSize}-->
   <operation name="poolGetMaxBlockSize" type="std::uint_fast16_t" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();
std::uint_fast16_t const max_size =
    QF_EPOOL_EVENT_SIZE_(priv_.ePool_[priv_.maxPool_ - 1U]);
QF_MEM_APP();
QF_CRIT_EXIT();

return max_size;</code>
   </operation>
   <!--${QF::QF-dyn::getPoolMin}-->
   <operation name="getPoolMin" type="std::uint_fast16_t" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QF::QF-dyn::getPoolMin::poolNum}-->
    <parameter name="poolNum" type="std::uint_fast8_t const"/>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_REQUIRE_INCRIT(400, (poolNum &lt;= QF_MAX_EPOOL)
                  &amp;&amp; (0U &lt; poolNum) &amp;&amp; (poolNum &lt;= priv_.maxPool_));

std::uint_fast16_t const min = static_cast&lt;std::uint_fast16_t&gt;(
    priv_.ePool_[poolNum - 1U].getNMin());

QF_MEM_APP();
QF_CRIT_EXIT();

return min;</code>
   </operation>
   <!--${QF::QF-dyn::newX_}-->
   <operation name="newX_" type="QEvt *" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QF::QF-dyn::newX_::evtSize}-->
    <parameter name="evtSize" type="std::uint_fast16_t const"/>
    <!--${QF::QF-dyn::newX_::margin}-->
    <parameter name="margin" type="std::uint_fast16_t const"/>
    <!--${QF::QF-dyn::newX_::sig}-->
    <parameter name="sig" type="enum_t const"/>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

// find the pool id that fits the requested event size...
std::uint_fast8_t poolNum = 0U; // zero-based poolNum initially
for (; poolNum &lt; priv_.maxPool_; ++poolNum) {
    if (evtSize &lt;= QF_EPOOL_EVENT_SIZE_(priv_.ePool_[poolNum])) {
        break;
    }
}

// precondition:
// - cannot run out of registered pools
Q_REQUIRE_INCRIT(300, poolNum &lt; priv_.maxPool_);

++poolNum; // convert to 1-based poolNum

QF_MEM_APP();
QF_CRIT_EXIT();

// get event e (port-dependent)...
QEvt *e;
#ifdef Q_SPY
QF_EPOOL_GET_(priv_.ePool_[poolNum - 1U], e,
              ((margin != NO_MARGIN) ? margin : 0U),
              static_cast&lt;std::uint_fast8_t&gt;(QS_EP_ID) + poolNum);
#else
QF_EPOOL_GET_(priv_.ePool_[poolNum - 1U], e,
              ((margin != NO_MARGIN) ? margin : 0U), 0U);
#endif

if (e != nullptr) { // was e allocated correctly?
    e-&gt;sig     = static_cast&lt;QSignal&gt;(sig); // set the signal
    e-&gt;evtTag_ = static_cast&lt;std::uint8_t&gt;((poolNum &lt;&lt; 4U) | 0x0FU);
    e-&gt;refCtr_ = 0U; // initialize the reference counter to 0

    QS_CRIT_ENTRY();
    QS_MEM_SYS();
    QS_BEGIN_PRE(QS_QF_NEW,
            static_cast&lt;std::uint_fast8_t&gt;(QS_EP_ID) + poolNum)
        QS_TIME_PRE();        // timestamp
        QS_EVS_PRE(evtSize);  // the size of the event
        QS_SIG_PRE(sig);      // the signal of the event
    QS_END_PRE()
    QS_MEM_APP();
    QS_CRIT_EXIT();
}
else { // event was not allocated

    QF_CRIT_ENTRY();
    // This assertion means that the event allocation failed,
    // and this failure cannot be tolerated. The most frequent
    // reason is an event leak in the application.
    Q_ASSERT_INCRIT(320, margin != NO_MARGIN);

    QS_MEM_SYS();
    QS_BEGIN_PRE(QS_QF_NEW_ATTEMPT,
            static_cast&lt;std::uint_fast8_t&gt;(QS_EP_ID) + poolNum)
        QS_TIME_PRE();        // timestamp
        QS_EVS_PRE(evtSize);  // the size of the event
        QS_SIG_PRE(sig);      // the signal of the event
    QS_END_PRE()
    QS_MEM_APP();

    QF_CRIT_EXIT();
}

// the returned event e is guaranteed to be valid (not NULL)
// if we can't tolerate failed allocation
return e;</code>
   </operation>
   <!--${QF::QF-dyn::gc}-->
   <operation name="gc" type="void" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QF::QF-dyn::gc::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
Q_REQUIRE_INCRIT(400, e != nullptr);
Q_INVARIANT_INCRIT(401, e-&gt;verify_());

std::uint_fast8_t const poolNum = e-&gt;getPoolNum_();

if (poolNum != 0U) { // is it a pool event (mutable)?
    QF_MEM_SYS();

    if (e-&gt;refCtr_ &gt; 1U) { // isn't this the last reference?

        QS_BEGIN_PRE(QS_QF_GC_ATTEMPT,
                static_cast&lt;std::uint_fast8_t&gt;(QS_EP_ID) + poolNum)
            QS_TIME_PRE();       // timestamp
            QS_SIG_PRE(e-&gt;sig);  // the signal of the event
            QS_2U8_PRE(poolNum, e-&gt;refCtr_);
        QS_END_PRE()

        QEvt_refCtr_dec_(e); // decrement the ref counter

        QF_MEM_APP();
        QF_CRIT_EXIT();
    }
    else { // this is the last reference to this event, recycle it

        QS_BEGIN_PRE(QS_QF_GC,
                static_cast&lt;std::uint_fast8_t&gt;(QS_EP_ID) + poolNum)
            QS_TIME_PRE();       // timestamp
            QS_SIG_PRE(e-&gt;sig);  // the signal of the event
            QS_2U8_PRE(poolNum, e-&gt;refCtr_);
        QS_END_PRE()

        // pool number must be in range
        Q_ASSERT_INCRIT(410, (poolNum &lt;= priv_.maxPool_)
                              &amp;&amp; (poolNum &lt;= QF_MAX_EPOOL));
        QF_MEM_APP();
        QF_CRIT_EXIT();

        // NOTE: casting 'const' away is legit because it's a pool event
#ifdef Q_SPY
        QF_EPOOL_PUT_(priv_.ePool_[poolNum - 1U],
            QF_CONST_CAST_(QEvt*, e),
            static_cast&lt;std::uint_fast8_t&gt;(QS_EP_ID) + poolNum);
#else
        QF_EPOOL_PUT_(priv_.ePool_[poolNum - 1U],
            QF_CONST_CAST_(QEvt*, e), 0U);
#endif
    }
}
else {
    QF_CRIT_EXIT();
}</code>
   </operation>
   <!--${QF::QF-dyn::newRef_}-->
   <operation name="newRef_" type="QEvt const *" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QF::QF-dyn::newRef_::e}-->
    <parameter name="e" type="QEvt const * const"/>
    <!--${QF::QF-dyn::newRef_::evtRef}-->
    <parameter name="evtRef" type="QEvt const * const"/>
    <code>#ifdef Q_UNSAFE
Q_UNUSED_PAR(evtRef);
#endif

QF_CRIT_STAT
QF_CRIT_ENTRY();

Q_REQUIRE_INCRIT(500, e != nullptr);
Q_INVARIANT_INCRIT(501, e-&gt;verify_());

std::uint_fast8_t const poolNum = e-&gt;getPoolNum_();
Q_UNUSED_PAR(poolNum); // might be unused

Q_REQUIRE_INCRIT(501, (poolNum != 0U)
    &amp;&amp; (evtRef == nullptr));

QEvt_refCtr_inc_(e); // increments the ref counter

QS_MEM_SYS();
QS_BEGIN_PRE(QS_QF_NEW_REF,
        static_cast&lt;std::uint_fast8_t&gt;(QS_EP_ID) + poolNum)
    QS_TIME_PRE();       // timestamp
    QS_SIG_PRE(e-&gt;sig);  // the signal of the event
    QS_2U8_PRE(poolNum, e-&gt;refCtr_);
QS_END_PRE()
QS_MEM_APP();

QF_CRIT_EXIT();

return e;</code>
   </operation>
   <!--${QF::QF-dyn::deleteRef_}-->
   <operation name="deleteRef_" type="void" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QF::QF-dyn::deleteRef_::evtRef}-->
    <parameter name="evtRef" type="QEvt const * const"/>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();

QEvt const * const e = evtRef;
Q_REQUIRE_INCRIT(600, e != nullptr);
Q_INVARIANT_INCRIT(601, e-&gt;verify_());

#ifdef Q_SPY
std::uint_fast8_t const poolNum = e-&gt;getPoolNum_();
#endif

QS_MEM_SYS();
QS_BEGIN_PRE(QS_QF_DELETE_REF,
        static_cast&lt;std::uint_fast8_t&gt;(QS_EP_ID) + poolNum)
    QS_TIME_PRE();       // timestamp
    QS_SIG_PRE(e-&gt;sig);  // the signal of the event
    QS_2U8_PRE(poolNum, e-&gt;refCtr_);
QS_END_PRE()
QS_MEM_APP();

QF_CRIT_EXIT();

#if (QF_MAX_EPOOL &gt; 0U)
gc(e); // recycle the referenced event
#endif</code>
   </operation>
   <!--${QF::QF-dyn::q_new}-->
   <operation name="q_new?ndef QEVT_PAR_INIT" type="template&lt;class evtT_&gt;&#10;evtT_ *" visibility="0x00" properties="0x02">
    <!--${QF::QF-dyn::q_new::sig}-->
    <parameter name="sig" type="enum_t const"/>
    <code>return static_cast&lt;evtT_*&gt;(
    QP::QF::newX_(sizeof(evtT_), QP::QF::NO_MARGIN, sig));</code>
   </operation>
   <!--${QF::QF-dyn::q_new}-->
   <operation name="q_new?def QEVT_PAR_INIT" type="template&lt;class evtT_, typename... Args&gt;&#10;evtT_ *" visibility="0x00" properties="0x02">
    <!--${QF::QF-dyn::q_new::sig}-->
    <parameter name="sig" type="enum_t const"/>
    <!--${QF::QF-dyn::q_new::args}-->
    <parameter name="args" type="Args..."/>
    <code>evtT_ *e = static_cast&lt;evtT_*&gt;(
    QP::QF::newX_(sizeof(evtT_), QP::QF::NO_MARGIN, sig));
e-&gt;init(args...); // e cannot be nullptr
return e;</code>
   </operation>
   <!--${QF::QF-dyn::q_new_x}-->
   <operation name="q_new_x?ndef QEVT_PAR_INIT" type="template&lt;class evtT_&gt;&#10;evtT_ *" visibility="0x00" properties="0x02">
    <!--${QF::QF-dyn::q_new_x::margin}-->
    <parameter name="margin" type="std::uint_fast16_t const"/>
    <!--${QF::QF-dyn::q_new_x::sig}-->
    <parameter name="sig" type="enum_t const"/>
    <code>return static_cast&lt;evtT_*&gt;(QP::QF::newX_(sizeof(evtT_), margin, sig));</code>
   </operation>
   <!--${QF::QF-dyn::q_new_x}-->
   <operation name="q_new_x?def QEVT_PAR_INIT" type="template&lt;class evtT_, typename... Args&gt;&#10;evtT_ *" visibility="0x00" properties="0x02">
    <!--${QF::QF-dyn::q_new_x::margin}-->
    <parameter name="margin" type="std::uint_fast16_t const"/>
    <!--${QF::QF-dyn::q_new_x::sig}-->
    <parameter name="sig" type="enum_t const"/>
    <!--${QF::QF-dyn::q_new_x::args}-->
    <parameter name="args" type="Args..."/>
    <code>evtT_ *e = static_cast&lt;evtT_*&gt;(QP::QF::newX_(sizeof(evtT_), margin, sig));
if (e != nullptr) {
    e-&gt;init(args...);
}
return e;</code>
   </operation>
   <!--${QF::QF-dyn::q_new_ref}-->
   <operation name="q_new_ref" type="template&lt;class evtT_&gt;&#10;void" visibility="0x00" properties="0x02">
    <!--${QF::QF-dyn::q_new_ref::e}-->
    <parameter name="e" type="QP::QEvt const * const"/>
    <!--${QF::QF-dyn::q_new_ref::evtRef}-->
    <parameter name="evtRef" type="evtT_ const *&amp;"/>
    <code>evtRef = static_cast&lt;evtT_ const *&gt;(QP::QF::newRef_(e, evtRef));</code>
   </operation>
   <!--${QF::QF-dyn::q_delete_ref}-->
   <operation name="q_delete_ref" type="template&lt;class evtT_&gt; void" visibility="0x00" properties="0x02">
    <!--${QF::QF-dyn::q_delete_ref::evtRef}-->
    <parameter name="evtRef" type="evtT_ const *&amp;"/>
    <code>QP::QF::deleteRef_(evtRef);
evtRef = nullptr;</code>
   </operation>
   <!--${QF::QF-dyn::newXfromISR_}-->
   <operation name="newXfromISR_?def QF_ISR_API" type="QEvt *" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QF::QF-dyn::newXfromISR_::evtSize}-->
    <parameter name="evtSize" type="std::uint_fast16_t const"/>
    <!--${QF::QF-dyn::newXfromISR_::margin}-->
    <parameter name="margin" type="std::uint_fast16_t const"/>
    <!--${QF::QF-dyn::newXfromISR_::sig}-->
    <parameter name="sig" type="enum_t const"/>
   </operation>
   <!--${QF::QF-dyn::gcFromISR}-->
   <operation name="gcFromISR?def QF_ISR_API" type="void" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QF::QF-dyn::gcFromISR::e}-->
    <parameter name="e" type="QEvt const *"/>
   </operation>
  </package>
 </package>
 <!--${QF-extern-C}-->
 <package name="QF-extern-C" stereotype="0x02">
  <!--${QF-extern-C::QF_onContextSw}-->
  <operation name="QF_onContextSw?def QF_ON_CONTEXT_SW" type="void" visibility="0x00" properties="0x00">
   <!--${QF-extern-C::QF_onContextSw::prev}-->
   <parameter name="prev" type="QP::QActive *"/>
   <!--${QF-extern-C::QF_onContextSw::next}-->
   <parameter name="next" type="QP::QActive *"/>
  </operation>
 </package>
 <!--${QF-macros}-->
 <package name="QF-macros" stereotype="0x02">
  <!--${QF-macros::Q_PRIO}-->
  <operation name="Q_PRIO" type="QP::QPrioSpec" visibility="0x03" properties="0x02">
   <!--${QF-macros::Q_PRIO::prio_}-->
   <parameter name="prio_" type="std::uint8_t"/>
   <!--${QF-macros::Q_PRIO::pthre_}-->
   <parameter name="pthre_" type="std::uint8_t"/>
   <code>\
    (static_cast&lt;QP::QPrioSpec&gt;((prio_) | (pthre_) &lt;&lt; 8U))</code>
  </operation>
  <!--${QF-macros::Q_NEW}-->
  <operation name="Q_NEW?ndef QEVT_PAR_INIT" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::Q_NEW::evtT_}-->
   <parameter name="evtT_" type="&lt;event class&gt;"/>
   <!--${QF-macros::Q_NEW::sig_}-->
   <parameter name="sig_" type="QP::QSignal"/>
   <code>(QP::QF::q_new&lt;evtT_&gt;((sig_)))</code>
  </operation>
  <!--${QF-macros::Q_NEW}-->
  <operation name="Q_NEW?def QEVT_PAR_INIT" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::Q_NEW::evtT_}-->
   <parameter name="evtT_" type="&lt;event class&gt;"/>
   <!--${QF-macros::Q_NEW::sig_}-->
   <parameter name="sig_" type="QP::QSignal"/>
   <!--${QF-macros::Q_NEW::...}-->
   <parameter name="..." type="__VA_ARGS__"/>
   <code>(QP::QF::q_new&lt;evtT_&gt;((sig_), __VA_ARGS__))</code>
  </operation>
  <!--${QF-macros::Q_NEW_X}-->
  <operation name="Q_NEW_X?ndef QEVT_PAR_INIT" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::Q_NEW_X::evtT_}-->
   <parameter name="evtT_" type="&lt;event class&gt;"/>
   <!--${QF-macros::Q_NEW_X::margin_}-->
   <parameter name="margin_" type="std::uint16_t"/>
   <!--${QF-macros::Q_NEW_X::sig_}-->
   <parameter name="sig_" type="QP::QSignal"/>
   <code>(QP::QF::q_new_x&lt;evtT_&gt;((margin_), (sig_)))</code>
  </operation>
  <!--${QF-macros::Q_NEW_X}-->
  <operation name="Q_NEW_X?def QEVT_PAR_INIT" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::Q_NEW_X::evtT_}-->
   <parameter name="evtT_" type="&lt;event class&gt;"/>
   <!--${QF-macros::Q_NEW_X::margin_}-->
   <parameter name="margin_" type="std::uint16_t"/>
   <!--${QF-macros::Q_NEW_X::sig_}-->
   <parameter name="sig_" type="QP::QSignal"/>
   <!--${QF-macros::Q_NEW_X::...}-->
   <parameter name="..." type="__VA_ARGS__"/>
   <code>(QP::QF::q_new_x&lt;evtT_&gt;((margin_), (sig_), __VA_ARGS__))</code>
  </operation>
  <!--${QF-macros::Q_NEW_REF}-->
  <operation name="Q_NEW_REF" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::Q_NEW_REF::evtRef_}-->
   <parameter name="evtRef_" type="&lt;event class&gt;"/>
   <!--${QF-macros::Q_NEW_REF::evtT_}-->
   <parameter name="evtT_" type="&lt;event class&gt;"/>
   <code>(QP::QF::q_new_ref&lt;evtT_&gt;(e, (evtRef_)))</code>
  </operation>
  <!--${QF-macros::Q_DELETE_REF}-->
  <operation name="Q_DELETE_REF" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::Q_DELETE_REF::evtRef_}-->
   <parameter name="evtRef_" type="&lt;event class&gt;"/>
   <code>do { \
    QP::QF::deleteRef_((evtRef_)); \
    (evtRef_) = nullptr; \
} while (false)</code>
  </operation>
  <!--${QF-macros::PUBLISH}-->
  <operation name="PUBLISH?def Q_SPY" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::PUBLISH::e_}-->
   <parameter name="e_" type="QP::QEvt const *"/>
   <!--${QF-macros::PUBLISH::sender_}-->
   <parameter name="sender_" type="&lt;void const *&gt;"/>
   <code>\
    publish_((e_), (sender_), (sender_)-&gt;getPrio())</code>
  </operation>
  <!--${QF-macros::PUBLISH}-->
  <operation name="PUBLISH?ndef Q_SPY" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::PUBLISH::e_}-->
   <parameter name="e_" type="QP::QEvt const *"/>
   <!--${QF-macros::PUBLISH::dummy}-->
   <parameter name="dummy" type=""/>
   <code>publish_((e_), nullptr, 0U)</code>
  </operation>
  <!--${QF-macros::POST}-->
  <operation name="POST?def Q_SPY" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::POST::e_}-->
   <parameter name="e_" type="QP::QEvt const *"/>
   <!--${QF-macros::POST::sender_}-->
   <parameter name="sender_" type="&lt;sender *&gt;"/>
   <code>post_((e_), QP::QF::NO_MARGIN, (sender_))</code>
  </operation>
  <!--${QF-macros::POST}-->
  <operation name="POST?ndef Q_SPY" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::POST::e_}-->
   <parameter name="e_" type="QP::QEvt const *"/>
   <!--${QF-macros::POST::dummy}-->
   <parameter name="dummy" type=""/>
   <code>post_((e_), QP::QF::NO_MARGIN, nullptr)</code>
  </operation>
  <!--${QF-macros::POST_X}-->
  <operation name="POST_X?def Q_SPY" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::POST_X::e_}-->
   <parameter name="e_" type="QP::QEvt const *"/>
   <!--${QF-macros::POST_X::margin_}-->
   <parameter name="margin_" type="std::uint16_t"/>
   <!--${QF-macros::POST_X::sender_}-->
   <parameter name="sender_" type="&lt;sender *&gt;"/>
   <code>\
    post_((e_), (margin_), (sender_))</code>
  </operation>
  <!--${QF-macros::POST_X}-->
  <operation name="POST_X?ndef Q_SPY" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::POST_X::e_}-->
   <parameter name="e_" type="QP::QEvt const *"/>
   <!--${QF-macros::POST_X::margin_}-->
   <parameter name="margin_" type="std::uint16_t"/>
   <!--${QF-macros::POST_X::dummy}-->
   <parameter name="dummy" type=""/>
   <code>post_((e_), (margin_), nullptr)</code>
  </operation>
  <!--${QF-macros::TICK_X}-->
  <operation name="TICK_X?def Q_SPY" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::TICK_X::tickRate_}-->
   <parameter name="tickRate_" type="std::uint_fast8_t const"/>
   <!--${QF-macros::TICK_X::sender_}-->
   <parameter name="sender_" type="&lt;void const *&gt;"/>
   <code>tick((tickRate_), (sender_))</code>
  </operation>
  <!--${QF-macros::TICK_X}-->
  <operation name="TICK_X?ndef Q_SPY" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::TICK_X::tickRate_}-->
   <parameter name="tickRate_" type="std::uint_fast8_t const"/>
   <!--${QF-macros::TICK_X::dummy}-->
   <parameter name="dummy" type=""/>
   <code>tick((tickRate_), nullptr)</code>
  </operation>
  <!--${QF-macros::TICK}-->
  <operation name="TICK" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::TICK::sender_}-->
   <parameter name="sender_" type="&lt;sender *&gt;"/>
   <code>TICK_X(0U, (sender_))</code>
  </operation>
  <!--${QF-macros::TRIG}-->
  <operation name="TRIG?def Q_SPY" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::TRIG::sender_}-->
   <parameter name="sender_" type="&lt;void const *&gt;"/>
   <code>trig_((sender_))</code>
  </operation>
  <!--${QF-macros::TRIG}-->
  <operation name="TRIG?ndef Q_SPY" type="void" visibility="0x03" properties="0x00">
   <!--${QF-macros::TRIG::sender_}-->
   <parameter name="sender_" type="&lt;void const *&gt;"/>
   <code>trig_(nullptr)</code>
  </operation>
  <!--${QF-macros::QF_CRIT_EXIT_NOP}-->
  <operation name="QF_CRIT_EXIT_NOP?ndef QF_CRIT_EXIT_NOP" type="void" visibility="0x03" properties="0x00">
   <code>(static_cast&lt;void&gt;(0))</code>
  </operation>
  <!--${QF-macros::QF_MEM_SYS}-->
  <operation name="QF_MEM_SYS?ndef QF_MEM_SYS" type="void" visibility="0x03" properties="0x00">
   <code>(static_cast&lt;void&gt;(0))</code>
  </operation>
  <!--${QF-macros::QF_MEM_APP}-->
  <operation name="QF_MEM_APP?ndef QF_MEM_APP" type="void" visibility="0x03" properties="0x00">
   <code>(static_cast&lt;void&gt;(0))</code>
  </operation>
 </package>
 <!--${QF_EPOOL-impl}-->
 <package name="QF_EPOOL-impl" stereotype="0x02">
  <!--${QF_EPOOL-impl::QF_EPOOL_TYPE_}-->
  <attribute name="QF_EPOOL_TYPE_" type="" visibility="0x03" properties="0x00">
   <documentation>Native QF event pool</documentation>
   <code>QMPool</code>
  </attribute>
  <!--${QF_EPOOL-impl::QF_EPOOL_INIT_}-->
  <operation name="QF_EPOOL_INIT_" type="" visibility="0x03" properties="0x00">
   <documentation>Native QF event pool initialization</documentation>
   <!--${QF_EPOOL-impl::QF_EPOOL_INIT_::p_}-->
   <parameter name="p_" type="QMPool *"/>
   <!--${QF_EPOOL-impl::QF_EPOOL_INIT_::poolSto_}-->
   <parameter name="poolSto_" type="void *"/>
   <!--${QF_EPOOL-impl::QF_EPOOL_INIT_::poolSize_}-->
   <parameter name="poolSize_" type="std::uint_fast32_t"/>
   <!--${QF_EPOOL-impl::QF_EPOOL_INIT_::evtSize_}-->
   <parameter name="evtSize_" type="std::uint_fast16_t"/>
   <code>\
    (p_).init((poolSto_), (poolSize_), (evtSize_))</code>
  </operation>
  <!--${QF_EPOOL-impl::QF_EPOOL_EVENT_SIZE_}-->
  <operation name="QF_EPOOL_EVENT_SIZE_" type="" visibility="0x03" properties="0x00">
   <documentation>Native QF event pool event-size getter</documentation>
   <!--${QF_EPOOL-impl::QF_EPOOL_EVENT_S~::p_}-->
   <parameter name="p_" type="QMPool const *"/>
   <code>((p_).getBlockSize())</code>
  </operation>
  <!--${QF_EPOOL-impl::QF_EPOOL_GET_}-->
  <operation name="QF_EPOOL_GET_" type="" visibility="0x03" properties="0x00">
   <documentation>Native QF event pool get-event</documentation>
   <!--${QF_EPOOL-impl::QF_EPOOL_GET_::p_}-->
   <parameter name="p_" type="QMPool *"/>
   <!--${QF_EPOOL-impl::QF_EPOOL_GET_::e_}-->
   <parameter name="e_" type="QEvt *"/>
   <!--${QF_EPOOL-impl::QF_EPOOL_GET_::m_}-->
   <parameter name="m_" type="std::uint_fast16_t"/>
   <!--${QF_EPOOL-impl::QF_EPOOL_GET_::qsId_}-->
   <parameter name="qsId_" type="std::uint8_t"/>
   <code>\
    ((e_) = static_cast&lt;QEvt *&gt;((p_).get((m_), (qsId_))))</code>
  </operation>
  <!--${QF_EPOOL-impl::QF_EPOOL_PUT_}-->
  <operation name="QF_EPOOL_PUT_" type="" visibility="0x03" properties="0x00">
   <documentation>Native QF event pool put-event</documentation>
   <!--${QF_EPOOL-impl::QF_EPOOL_PUT_::p_}-->
   <parameter name="p_" type="QMPool *"/>
   <!--${QF_EPOOL-impl::QF_EPOOL_PUT_::e_}-->
   <parameter name="e_" type="QEvt *"/>
   <!--${QF_EPOOL-impl::QF_EPOOL_PUT_::qsId_}-->
   <parameter name="qsId_" type="std::uint8_t"/>
   <code>((p_).put((e_), (qsId_)))</code>
  </operation>
 </package>
 <!--${QV}-->
 <package name="QV" stereotype="0x05" namespace="QP::">
  <!--${QV::QV-base}-->
  <package name="QV-base" stereotype="0x02" namespace="QV::">
   <!--${QV::QV-base::Attr}-->
   <class name="Attr">
    <!--${QV::QV-base::Attr::readySet}-->
    <attribute name="readySet" type="QPSet" visibility="0x00" properties="0x00"/>
    <!--${QV::QV-base::Attr::schedCeil}-->
    <attribute name="schedCeil" type="std::uint_fast8_t" visibility="0x00" properties="0x00"/>
    <!--${QV::QV-base::Attr::readySet_dis}-->
    <attribute name="readySet_dis?ndef Q_UNSAFE" type="QPSet" visibility="0x00" properties="0x00"/>
    <!--${QV::QV-base::Attr::schedCeil_dis}-->
    <attribute name="schedCeil_dis?ndef Q_UNSAFE" type="std::uint_fast8_t" visibility="0x00" properties="0x00"/>
   </class>
   <!--${QV::QV-base::priv_}-->
   <attribute name="priv_" type="QV::Attr" visibility="0x00" properties="0x01"/>
   <!--${QV::QV-base::schedDisable}-->
   <operation name="schedDisable" type="void" visibility="0x00" properties="0x01">
    <!--${QV::QV-base::schedDisable::ceiling}-->
    <parameter name="ceiling" type="std::uint_fast8_t const"/>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_INVARIANT_INCRIT(102, priv_.schedCeil
    == static_cast&lt;std::uint_fast8_t&gt;(~priv_.schedCeil_dis));

if (ceiling &gt; priv_.schedCeil) { // raising the scheduler ceiling?

    QS_BEGIN_PRE(QS_SCHED_LOCK, 0U)
        QS_TIME_PRE();   // timestamp
        // the previous sched ceiling &amp; new sched ceiling
        QS_2U8_PRE(static_cast&lt;std::uint8_t&gt;(priv_.schedCeil),
                    static_cast&lt;std::uint8_t&gt;(ceiling));
    QS_END_PRE()

    priv_.schedCeil = ceiling;
#ifndef Q_UNSAFE
    priv_.schedCeil_dis = static_cast&lt;std::uint_fast8_t&gt;(~ceiling);
#endif
}
QF_MEM_APP();
QF_CRIT_EXIT();</code>
   </operation>
   <!--${QV::QV-base::schedEnable}-->
   <operation name="schedEnable" type="void" visibility="0x00" properties="0x01">
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_INVARIANT_INCRIT(202, priv_.schedCeil
    == static_cast&lt;std::uint_fast8_t&gt;(~priv_.schedCeil_dis));

if (priv_.schedCeil != 0U) { // actually enabling the scheduler?

    QS_BEGIN_PRE(QS_SCHED_UNLOCK, 0U)
        QS_TIME_PRE(); // timestamp
        // current sched ceiling (old), previous sched ceiling (new)
        QS_2U8_PRE(static_cast&lt;std::uint8_t&gt;(priv_.schedCeil), 0U);
    QS_END_PRE()

    priv_.schedCeil = 0U;
#ifndef Q_UNSAFE
    priv_.schedCeil_dis = ~static_cast&lt;std::uint_fast8_t&gt;(0U);
#endif
}
QF_MEM_APP();
QF_CRIT_EXIT();</code>
   </operation>
   <!--${QV::QV-base::onIdle}-->
   <operation name="onIdle" type="void" visibility="0x00" properties="0x01"/>
  </package>
  <!--${QV::QF-cust}-->
  <package name="QF-cust" stereotype="0x02" namespace="QF::">
   <!--${QV::QF-cust::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x01">
    <code>bzero_(&amp;QF::priv_,                 sizeof(QF::priv_));
bzero_(&amp;QV::priv_,                 sizeof(QV::priv_));
bzero_(&amp;QActive::registry_[0],     sizeof(QActive::registry_));

#ifndef Q_UNSAFE
QV::priv_.readySet.update_(&amp;QV::priv_.readySet_dis);
QV::priv_.schedCeil_dis = ~static_cast&lt;std::uint_fast8_t&gt;(0U);
#endif

#ifdef QV_INIT
QV_INIT(); // port-specific initialization of the QV kernel
#endif</code>
   </operation>
   <!--${QV::QF-cust::stop}-->
   <operation name="stop" type="void" visibility="0x00" properties="0x01">
    <code>onCleanup(); // cleanup callback
// nothing else to do for the QV kernel</code>
   </operation>
   <!--${QV::QF-cust::run}-->
   <operation name="run" type="int_t" visibility="0x00" properties="0x01">
    <code>#ifdef Q_SPY
// produce the QS_QF_RUN trace record
QF_INT_DISABLE();
QF_MEM_SYS();
QS::beginRec_(QS_REC_NUM_(QS_QF_RUN));
QS::endRec_();
QF_MEM_APP();
QF_INT_ENABLE();
#endif // Q_SPY

onStartup(); // application-specific startup callback

QF_INT_DISABLE();
QF_MEM_SYS();

#ifdef QV_START
QV_START(); // port-specific startup of the QV kernel
#endif

#if (defined QF_ON_CONTEXT_SW) || (defined Q_SPY)
std::uint_fast8_t pprev = 0U; // previous prio.

#ifdef QF_ON_CONTEXT_SW
// officially switch to the idle cotext
QF_onContextSw(nullptr, nullptr);
#endif // def QF_ON_CONTEXT_SW

#endif // (defined QF_ON_CONTEXT_SW) || (defined Q_SPY)

for (;;) { // QV event loop...

    // check internal integrity (duplicate inverse storage)
    Q_INVARIANT_INCRIT(302,
         QV::priv_.readySet.verify_(&amp;QV::priv_.readySet_dis));
    // check internal integrity (duplicate inverse storage)
    Q_INVARIANT_INCRIT(303, QV::priv_.schedCeil
        == static_cast&lt;std::uint_fast8_t&gt;(~QV::priv_.schedCeil_dis));

    // find the maximum prio. AO ready to run
    std::uint_fast8_t const p = (QV::priv_.readySet.notEmpty()
                           ? QV::priv_.readySet.findMax()
                           : 0U);

    if (p &gt; QV::priv_.schedCeil) { // is it above the sched ceiling?
        QActive * const a = QActive::registry_[p];

#if (defined QF_ON_CONTEXT_SW) || (defined Q_SPY)
        QS_BEGIN_PRE(QS_SCHED_NEXT, p)
            QS_TIME_PRE();        // timestamp
            QS_2U8_PRE(static_cast&lt;std::uint8_t&gt;(p),
                        static_cast&lt;std::uint8_t&gt;(pprev));
        QS_END_PRE()

#ifdef QF_ON_CONTEXT_SW
        QF_onContextSw(((pprev != 0U)
                        ? QActive::registry_[pprev]
                        : nullptr), a);
#endif // QF_ON_CONTEXT_SW

        pprev = p; // update previous prio.
#endif // (defined QF_ON_CONTEXT_SW) || (defined Q_SPY)

        QF_MEM_APP();
        QF_INT_ENABLE();

        QEvt const * const e = a-&gt;get_();
        // NOTE QActive::get_() performs QF_MEM_APP() before return

        // dispatch event (virtual call)
        a-&gt;dispatch(e, a-&gt;getPrio());
#if (QF_MAX_EPOOL &gt; 0U)
        gc(e);
#endif
        QF_INT_DISABLE();
        QF_MEM_SYS();

        if (a-&gt;getEQueue().isEmpty()) { // empty queue?
            QV::priv_.readySet.remove(p);
#ifndef Q_UNSAFE
            QV::priv_.readySet.update_(&amp;QV::priv_.readySet_dis);
#endif
        }
    }
    else { // no AO ready to run --&gt; idle
#if (defined QF_ON_CONTEXT_SW) || (defined Q_SPY)
        if (pprev != 0U) {
            QS_BEGIN_PRE(QS_SCHED_IDLE, pprev)
                QS_TIME_PRE();    // timestamp
                QS_U8_PRE(static_cast&lt;std::uint8_t&gt;(pprev));
            QS_END_PRE()

#ifdef QF_ON_CONTEXT_SW
            QF_onContextSw(QActive::registry_[pprev], nullptr);
#endif // QF_ON_CONTEXT_SW

            pprev = 0U; // update previous prio
        }
#endif // (defined QF_ON_CONTEXT_SW) || (defined Q_SPY)

        QF_MEM_APP();

        // QV::onIdle() must be called with interrupts DISABLED
        // because the determination of the idle condition (all event
        // queues empty) can change at any time by an interrupt posting
        // events to a queue.
        //
        // NOTE: QV::onIdle() MUST enable interrupts internally,
        // ideally at the same time as putting the CPU into a power-
        // saving mode.
        QV::onIdle();

        QF_INT_DISABLE();
        QF_MEM_SYS();
    }
}
#ifdef __GNUC__ // GNU compiler?
return 0;
#endif</code>
   </operation>
  </package>
  <!--${QV::QActive}-->
  <class name="QActive" superclass="qpcpp::QAsm">
   <!--${QV::QActive::start}-->
   <operation name="start" type="void" visibility="0x00" properties="0x04">
    <!--${QV::QActive::start::prioSpec}-->
    <parameter name="prioSpec" type="QPrioSpec const"/>
    <!--${QV::QActive::start::qSto}-->
    <parameter name="qSto" type="QEvtPtr * const"/>
    <!--${QV::QActive::start::qLen}-->
    <parameter name="qLen" type="std::uint_fast16_t const"/>
    <!--${QV::QActive::start::stkSto}-->
    <parameter name="stkSto" type="void * const"/>
    <!--${QV::QActive::start::stkSize}-->
    <parameter name="stkSize" type="std::uint_fast16_t const"/>
    <!--${QV::QActive::start::par}-->
    <parameter name="par" type="void const * const"/>
    <code>Q_UNUSED_PAR(stkSto);  // not needed in QV
Q_UNUSED_PAR(stkSize); // not needed in QV

QF_CRIT_STAT
QF_CRIT_ENTRY();
Q_REQUIRE_INCRIT(300, stkSto == nullptr);
QF_CRIT_EXIT();

m_prio  = static_cast&lt;std::uint8_t&gt;(prioSpec &amp; 0xFFU); //  QF-prio.
m_pthre = 0U; // not used
register_(); // make QF aware of this AO

m_eQueue.init(qSto, qLen); // initialize QEQueue of this AO

this-&gt;init(par, m_prio); // take the top-most initial tran. (virtual)
QS_FLUSH(); // flush the trace buffer to the host</code>
   </operation>
  </class>
 </package>
 <!--${QV-impl}-->
 <package name="QV-impl" stereotype="0x02">
  <!--${QV-impl::QF_SCHED_STAT_}-->
  <attribute name="QF_SCHED_STAT_" type="" visibility="0x03" properties="0x00"/>
  <!--${QV-impl::QF_SCHED_LOCK_}-->
  <operation name="QF_SCHED_LOCK_" type="" visibility="0x03" properties="0x00">
   <!--${QV-impl::QF_SCHED_LOCK_::dummy}-->
   <parameter name="dummy" type=""/>
   <code>(static_cast&lt;void&gt;(0))</code>
  </operation>
  <!--${QV-impl::QF_SCHED_UNLOCK_}-->
  <operation name="QF_SCHED_UNLOCK_" type="" visibility="0x03" properties="0x00">
   <code>(static_cast&lt;void&gt;(0))</code>
  </operation>
  <!--${QV-impl::QACTIVE_EQUEUE_WAIT_}-->
  <operation name="QACTIVE_EQUEUE_WAIT_" type="" visibility="0x03" properties="0x00">
   <!--${QV-impl::QACTIVE_EQUEUE_W~::me_}-->
   <parameter name="me_" type="QP::QActive *"/>
   <code>(static_cast&lt;void&gt;(0))</code>
  </operation>
  <!--${QV-impl::QACTIVE_EQUEUE_SIGNAL_}-->
  <operation name="QACTIVE_EQUEUE_SIGNAL_?ndef Q_UNSAFE" type="" visibility="0x03" properties="0x00">
   <!--${QV-impl::QACTIVE_EQUEUE_S~::me_}-->
   <parameter name="me_" type="QP::QActive *"/>
   <code>\
    QV::priv_.readySet.insert((me_)-&gt;m_prio); \
    QV::priv_.readySet.update_(&amp;QV::priv_.readySet_dis)</code>
  </operation>
  <!--${QV-impl::QACTIVE_EQUEUE_SIGNAL_}-->
  <operation name="QACTIVE_EQUEUE_SIGNAL_?def Q_UNSAFE" type="" visibility="0x03" properties="0x00">
   <!--${QV-impl::QACTIVE_EQUEUE_S~::me_}-->
   <parameter name="me_" type="QP::QActive *"/>
   <code>\
    (QV::priv_.readySet.insert((me_)-&gt;m_prio))</code>
  </operation>
 </package>
 <!--${QK}-->
 <package name="QK" stereotype="0x05" namespace="QP::">
  <!--${QK::QSchedStatus}-->
  <attribute name="QSchedStatus" type="using" visibility="0x04" properties="0x00">
   <code>= std::uint_fast8_t;</code>
  </attribute>
  <!--${QK::QK-base}-->
  <package name="QK-base" stereotype="0x02" namespace="QK::">
   <!--${QK::QK-base::schedLock}-->
   <operation name="schedLock" type="QSchedStatus" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QK::QK-base::schedLock::ceiling}-->
    <parameter name="ceiling" type="std::uint_fast8_t const"/>
    <code>QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_REQUIRE_INCRIT(100, !QK_ISR_CONTEXT_());
Q_INVARIANT_INCRIT(102, QK_priv_.lockCeil
    == static_cast&lt;std::uint_fast8_t&gt;(~QK_priv_.lockCeil_dis));

// first store the previous lock prio
QSchedStatus stat;
if (ceiling &gt; QK_priv_.lockCeil) { // raising the lock ceiling?
    QS_BEGIN_PRE(QS_SCHED_LOCK, QK_priv_.actPrio)
        QS_TIME_PRE();   // timestamp
        // the previous lock ceiling &amp; new lock ceiling
        QS_2U8_PRE(static_cast&lt;std::uint8_t&gt;(QK_priv_.lockCeil),
                    static_cast&lt;std::uint8_t&gt;(ceiling));
    QS_END_PRE()

    // previous status of the lock
    stat = static_cast&lt;QSchedStatus&gt;(QK_priv_.lockCeil);

    // new status of the lock
    QK_priv_.lockCeil = ceiling;
#ifndef Q_UNSAFE
    QK_priv_.lockCeil_dis = static_cast&lt;std::uint_fast8_t&gt;(~ceiling);
#endif
}
else {
    stat = 0xFFU; // scheduler not locked
}

QF_MEM_APP();
QF_CRIT_EXIT();

return stat; // return the status to be saved in a stack variable</code>
   </operation>
   <!--${QK::QK-base::schedUnlock}-->
   <operation name="schedUnlock" type="void" visibility="0x00" properties="0x01">
    <specifiers>noexcept</specifiers>
    <!--${QK::QK-base::schedUnlock::prevCeil}-->
    <parameter name="prevCeil" type="QSchedStatus const"/>
    <code>// has the scheduler been actually locked by the last QK::schedLock()?
if (prevCeil != 0xFFU) {
    QF_CRIT_STAT
    QF_CRIT_ENTRY();
    QF_MEM_SYS();

    Q_INVARIANT_INCRIT(202, QK_priv_.lockCeil
        == static_cast&lt;std::uint_fast8_t&gt;(~QK_priv_.lockCeil_dis));
    Q_REQUIRE_INCRIT(210, (!QK_ISR_CONTEXT_())
                          &amp;&amp; (QK_priv_.lockCeil &gt; prevCeil));

    QS_BEGIN_PRE(QS_SCHED_UNLOCK, QK_priv_.actPrio)
        QS_TIME_PRE(); // timestamp
        // current lock ceiling (old), previous lock ceiling (new)
        QS_2U8_PRE(static_cast&lt;std::uint8_t&gt;(QK_priv_.lockCeil),
                    static_cast&lt;std::uint8_t&gt;(prevCeil));
    QS_END_PRE()

    // restore the previous lock ceiling
    QK_priv_.lockCeil = prevCeil;
#ifndef Q_UNSAFE
    QK_priv_.lockCeil_dis = static_cast&lt;std::uint_fast8_t&gt;(~prevCeil);
#endif

    // find if any AOs should be run after unlocking the scheduler
    if (QK_sched_() != 0U) { // preemption needed?
        QK_activate_(); // activate any unlocked AOs
    }

    QF_MEM_APP();
    QF_CRIT_EXIT();
}</code>
   </operation>
   <!--${QK::QK-base::onIdle}-->
   <operation name="onIdle" type="void" visibility="0x00" properties="0x01"/>
  </package>
  <!--${QK::QF-cust}-->
  <package name="QF-cust" stereotype="0x02" namespace="QF::">
   <!--${QK::QF-cust::init}-->
   <operation name="init" type="void" visibility="0x00" properties="0x01">
    <code>bzero_(&amp;QF::priv_,                 sizeof(QF::priv_));
bzero_(&amp;QK_priv_,                  sizeof(QK_priv_));
bzero_(&amp;QActive::registry_[0],     sizeof(QActive::registry_));

// setup the QK scheduler as initially locked and not running
QK_priv_.lockCeil = (QF_MAX_ACTIVE + 1U); // scheduler locked

#ifndef Q_UNSAFE
QK_priv_.readySet.update_(&amp;QK_priv_.readySet_dis);
QK_priv_.actPrio_dis  = static_cast&lt;std::uint_fast8_t&gt;(~QK_priv_.actPrio);
QK_priv_.nextPrio_dis = static_cast&lt;std::uint_fast8_t&gt;(~QK_priv_.nextPrio);
QK_priv_.actThre_dis  = static_cast&lt;std::uint_fast8_t&gt;(~QK_priv_.actThre);
QK_priv_.lockCeil_dis = static_cast&lt;std::uint_fast8_t&gt;(~QK_priv_.lockCeil);
#endif

#ifdef QK_INIT
QK_INIT(); // port-specific initialization of the QK kernel
#endif</code>
   </operation>
   <!--${QK::QF-cust::stop}-->
   <operation name="stop" type="void" visibility="0x00" properties="0x01">
    <code>onCleanup();  // cleanup callback
// nothing else to do for the QK preemptive kernel</code>
   </operation>
   <!--${QK::QF-cust::run}-->
   <operation name="run" type="int_t" visibility="0x00" properties="0x01">
    <code>#ifdef Q_SPY
// produce the QS_QF_RUN trace record
QF_INT_DISABLE();
QF_MEM_SYS();
QS::beginRec_(QS_REC_NUM_(QS_QF_RUN));
QS::endRec_();
QF_MEM_APP();
QF_INT_ENABLE();
#endif // Q_SPY

onStartup(); // application-specific startup callback

QF_INT_DISABLE();
QF_MEM_SYS();

#ifdef QK_START
QK_START(); // port-specific startup of the QK kernel
#endif

QK_priv_.lockCeil = 0U; // unlock the QK scheduler
#ifndef Q_UNSAFE
QK_priv_.lockCeil_dis = static_cast&lt;std::uint_fast8_t&gt;(~QK_priv_.lockCeil);
#endif

#ifdef QF_ON_CONTEXT_SW
// officially switch to the idle context
QF_onContextSw(nullptr, QActive::registry_[QK_priv_.nextPrio]);
#endif

// activate AOs to process events posted so far
if (QK_sched_() != 0U) {
    QK_activate_();
}

QF_MEM_APP();
QF_INT_ENABLE();

for (;;) { // QK idle loop...
    QK::onIdle(); // application-specific QK on-idle callback
}

#ifdef __GNUC__  // GNU compiler?
return 0;
#endif</code>
   </operation>
  </package>
  <!--${QK::QActive}-->
  <class name="QActive" superclass="QEP::QAsm">
   <!--${QK::QActive::start}-->
   <operation name="start" type="void" visibility="0x00" properties="0x04">
    <!--${QK::QActive::start::prioSpec}-->
    <parameter name="prioSpec" type="QPrioSpec const"/>
    <!--${QK::QActive::start::qSto}-->
    <parameter name="qSto" type="QEvtPtr * const"/>
    <!--${QK::QActive::start::qLen}-->
    <parameter name="qLen" type="std::uint_fast16_t const"/>
    <!--${QK::QActive::start::stkSto}-->
    <parameter name="stkSto" type="void * const"/>
    <!--${QK::QActive::start::stkSize}-->
    <parameter name="stkSize" type="std::uint_fast16_t const"/>
    <!--${QK::QActive::start::par}-->
    <parameter name="par" type="void const * const"/>
    <code>Q_UNUSED_PAR(stkSto);  // not needed in QK
Q_UNUSED_PAR(stkSize); // not needed in QK

QF_CRIT_STAT
QF_CRIT_ENTRY();
QF_MEM_SYS();

Q_REQUIRE_INCRIT(300, (!QK_ISR_CONTEXT_())
                 &amp;&amp; (stkSto == nullptr));
QF_MEM_APP();
QF_CRIT_EXIT();

m_prio  = static_cast&lt;std::uint8_t&gt;(prioSpec &amp; 0xFFU); // QF-prio.
m_pthre = static_cast&lt;std::uint8_t&gt;(prioSpec &gt;&gt; 8U); // preemption-thre.
register_(); // make QF aware of this AO

m_eQueue.init(qSto, qLen); // init the built-in queue

// top-most initial tran. (virtual call)
this-&gt;init(par, m_prio);
QS_FLUSH(); // flush the trace buffer to the host

// See if this AO needs to be scheduled if QK is already running
QF_CRIT_ENTRY();
QF_MEM_SYS();
if (QK_sched_() != 0U) { // activation needed?
    QK_activate_();
}
QF_MEM_APP();
QF_CRIT_EXIT();</code>
   </operation>
  </class>
 </package>
 <!--${QK-extern-C}-->
 <package name="QK-extern-C" stereotype="0x02">
  <!--${QK-extern-C::QK_Attr}-->
  <class name="QK_Attr">
   <!--${QK-extern-C::QK_Attr::readySet}-->
   <attribute name="readySet" type="QP::QPSet" visibility="0x00" properties="0x00"/>
   <!--${QK-extern-C::QK_Attr::actPrio}-->
   <attribute name="actPrio" type="std::uint_fast8_t" visibility="0x00" properties="0x00"/>
   <!--${QK-extern-C::QK_Attr::nextPrio}-->
   <attribute name="nextPrio" type="std::uint_fast8_t" visibility="0x00" properties="0x00"/>
   <!--${QK-extern-C::QK_Attr::actThre}-->
   <attribute name="actThre" type="std::uint_fast8_t" visibility="0x00" properties="0x00"/>
   <!--${QK-extern-C::QK_Attr::lockCeil}-->
   <attribute name="lockCeil" type="std::uint_fast8_t" visibility="0x00" properties="0x00"/>
   <!--${QK-extern-C::QK_Attr::intNest}-->
   <attribute name="intNest" type="std::uint_fast8_t" visibility="0x00" properties="0x00"/>
   <!--${QK-extern-C::QK_Attr::readySet_dis}-->
   <attribute name="readySet_dis?ndef Q_UNSAFE" type="QP::QPSet" visibility="0x00" properties="0x00"/>
   <!--${QK-extern-C::QK_Attr::actPrio_dis}-->
   <attribute name="actPrio_dis?ndef Q_UNSAFE" type="std::uint_fast8_t" visibility="0x00" properties="0x00"/>
   <!--${QK-extern-C::QK_Attr::nextPrio_dis}-->
   <attribute name="nextPrio_dis?ndef Q_UNSAFE" type="std::uint_fast8_t" visibility="0x00" properties="0x00"/>
   <!--${QK-extern-C::QK_Attr::actThre_dis}-->
   <attribute name="actThre_dis?ndef Q_UNSAFE" type="std::uint_fast8_t" visibility="0x00" properties="0x00"/>
   <!--${QK-extern-C::QK_Attr::lockCeil_dis}-->
   <attribute name="lockCeil_dis?ndef Q_UNSAFE" type="std::uint_fast8_t" visibility="0x00" properties="0x00"/>
  </class>
  <!--${QK-extern-C::QK_priv_}-->
  <attribute name="QK_priv_" type="QK_Attr" visibility="0x00" properties="0x00"/>
  <!--${QK-extern-C::QK_sched_}-->
  <operation name="QK_sched_" type="std::uint_fast8_t" visibility="0x00" properties="0x00">
   <specifiers>noexcept</specifiers>
   <code>// NOTE: this function is entered with interrupts DISABLED

Q_INVARIANT_INCRIT(402,
    QK_priv_.readySet.verify_(&amp;QK_priv_.readySet_dis));

std::uint_fast8_t p;
if (QK_priv_.readySet.isEmpty()) {
    p = 0U; // no activation needed
}
else {
    // find the highest-prio AO with non-empty event queue
    p = QK_priv_.readySet.findMax();

    Q_INVARIANT_INCRIT(412, QK_priv_.actThre
        == static_cast&lt;std::uint_fast8_t&gt;(~QK_priv_.actThre_dis));

    // is the AO's prio. below the active preemption-threshold?
    if (p &lt;= QK_priv_.actThre) {
        p = 0U; // no activation needed
    }
    else {
        Q_INVARIANT_INCRIT(422, QK_priv_.lockCeil
            == static_cast&lt;std::uint_fast8_t&gt;(~QK_priv_.lockCeil_dis));

        // is the AO's prio. below the lock-ceiling?
        if (p &lt;= QK_priv_.lockCeil) {
            p = 0U; // no activation needed
        }
        else {
            Q_INVARIANT_INCRIT(432, QK_priv_.nextPrio
                == static_cast&lt;std::uint_fast8_t&gt;(~QK_priv_.nextPrio_dis));
            QK_priv_.nextPrio = p; // next AO to run
#ifndef Q_UNSAFE
            QK_priv_.nextPrio_dis
                = static_cast&lt;std::uint_fast8_t&gt;(~QK_priv_.nextPrio);
#endif
        }
    }
}

return p;</code>
  </operation>
  <!--${QK-extern-C::QK_activate_}-->
  <operation name="QK_activate_" type="void" visibility="0x00" properties="0x00">
   <specifiers>noexcept</specifiers>
   <code>// NOTE: this function is entered with interrupts DISABLED

std::uint_fast8_t const prio_in = QK_priv_.actPrio; // save initial prio.
std::uint_fast8_t p = QK_priv_.nextPrio; // next prio to run

Q_INVARIANT_INCRIT(502,
   (prio_in == static_cast&lt;std::uint_fast8_t&gt;(~QK_priv_.actPrio_dis))
   &amp;&amp; (p == static_cast&lt;std::uint_fast8_t&gt;(~QK_priv_.nextPrio_dis)));
Q_REQUIRE_INCRIT(510, (prio_in &lt;= QF_MAX_ACTIVE)
   &amp;&amp; (0U &lt; p) &amp;&amp; (p &lt;= QF_MAX_ACTIVE));

#if (defined QF_ON_CONTEXT_SW) || (defined Q_SPY)
std::uint_fast8_t pprev = prio_in;
#endif // QF_ON_CONTEXT_SW || Q_SPY

QK_priv_.nextPrio = 0U; // clear for the next time
#ifndef Q_UNSAFE
QK_priv_.nextPrio_dis = static_cast&lt;std::uint_fast8_t&gt;(~QK_priv_.nextPrio);
#endif

std::uint_fast8_t pthre_in;
QP::QActive *a;
if (prio_in == 0U) { // preempting the idle thread?
    pthre_in = 0U;
}
else {
    a = QP::QActive::registry_[prio_in];
    Q_ASSERT_INCRIT(510, a != nullptr);

    pthre_in = static_cast&lt;std::uint_fast8_t&gt;(a-&gt;getPThre());
    Q_INVARIANT_INCRIT(511, pthre_in == static_cast&lt;std::uint_fast8_t&gt;(
        ~static_cast&lt;std::uint_fast8_t&gt;(a-&gt;m_pthre_dis) &amp; 0xFFU));
}

// loop until no more ready-to-run AOs of higher pthre than the initial
do  {
    a = QP::QActive::registry_[p]; // obtain the pointer to the AO
    Q_ASSERT_INCRIT(520, a != nullptr); // the AO must be registered
    std::uint_fast8_t const pthre
        = static_cast&lt;std::uint_fast8_t&gt;(a-&gt;getPThre());
    Q_INVARIANT_INCRIT(522, pthre == static_cast&lt;std::uint_fast8_t&gt;(
        ~static_cast&lt;std::uint_fast8_t&gt;(a-&gt;m_pthre_dis) &amp; 0xFFU));

    // set new active prio. and preemption-threshold
    QK_priv_.actPrio = p;
    QK_priv_.actThre = pthre;
#ifndef Q_UNSAFE
    QK_priv_.actPrio_dis = static_cast&lt;std::uint_fast8_t&gt;(~p);
    QK_priv_.actThre_dis = static_cast&lt;std::uint_fast8_t&gt;(~pthre);
#endif

#if (defined QF_ON_CONTEXT_SW) || (defined Q_SPY)
    if (p != pprev) { // changing threads?

        QS_BEGIN_PRE(QP::QS_SCHED_NEXT, p)
            QS_TIME_PRE();     // timestamp
            QS_2U8_PRE(p,      // prio. of the scheduled AO
                        pprev); // previous prio.
        QS_END_PRE()

#ifdef QF_ON_CONTEXT_SW
        QF_onContextSw(QP::QActive::registry_[pprev], a);
#endif // QF_ON_CONTEXT_SW

        pprev = p; // update previous prio.
    }
#endif // QF_ON_CONTEXT_SW || Q_SPY

    QF_MEM_APP();
    QF_INT_ENABLE(); // unconditionally enable interrupts

    QP::QEvt const * const e = a-&gt;get_();
    // NOTE QActive_get_() performs QF_MEM_APP() before return

    // dispatch event (virtual call)
    a-&gt;dispatch(e, a-&gt;getPrio());
#if (QF_MAX_EPOOL &gt; 0U)
    QP::QF::gc(e);
#endif

    // determine the next highest-prio. AO ready to run...
    QF_INT_DISABLE(); // unconditionally disable interrupts
    QF_MEM_SYS();

    // internal integrity check (duplicate inverse storage)
    Q_INVARIANT_INCRIT(532,
        QK_priv_.readySet.verify_(&amp;QK_priv_.readySet_dis));

    if (a-&gt;getEQueue().isEmpty()) { // empty queue?
        QK_priv_.readySet.remove(p);
#ifndef Q_UNSAFE
        QK_priv_.readySet.update_(&amp;QK_priv_.readySet_dis);
#endif
    }

    if (QK_priv_.readySet.isEmpty()) {
        p = 0U; // no activation needed
    }
    else {
        // find new highest-prio AO ready to run...
        p = QK_priv_.readySet.findMax();

        // is the new prio. below the initial preemption-threshold?
        if (p &lt;= pthre_in) {
            p = 0U; // no activation needed
        }
        else {
            Q_INVARIANT_INCRIT(542,
                QK_priv_.lockCeil == ~QK_priv_.lockCeil_dis);

            // is the AO's prio. below the lock preemption-threshold?
            if (p &lt;= QK_priv_.lockCeil) {
                p = 0U; // no activation needed
            }
            else {
                Q_ASSERT_INCRIT(550, p &lt;= QF_MAX_ACTIVE);
            }
        }
    }
} while (p != 0U);

// restore the active prio. and preemption-threshold
QK_priv_.actPrio = prio_in;
QK_priv_.actThre = pthre_in;
#ifndef Q_UNSAFE
QK_priv_.actPrio_dis = static_cast&lt;std::uint_fast8_t&gt;(~QK_priv_.actPrio);
QK_priv_.actThre_dis = static_cast&lt;std::uint_fast8_t&gt;(~QK_priv_.actThre);
#endif

#if (defined QF_ON_CONTEXT_SW) || (defined Q_SPY)
if (prio_in != 0U) { // resuming an active object?
    a = QP::QActive::registry_[prio_in]; // pointer to preempted AO

    QS_BEGIN_PRE(QP::QS_SCHED_NEXT, prio_in)
        QS_TIME_PRE();     // timestamp
        // prio. of the resumed AO, previous prio.
        QS_2U8_PRE(prio_in, pprev);
    QS_END_PRE()
}
else {  // resuming prio.==0 --&gt; idle
    a = nullptr; // QK idle loop

    QS_BEGIN_PRE(QP::QS_SCHED_IDLE, pprev)
        QS_TIME_PRE();     // timestamp
        QS_U8_PRE(pprev);  // previous prio.
    QS_END_PRE()
}

#ifdef QF_ON_CONTEXT_SW
QF_onContextSw(QP::QActive::registry_[pprev], a);
#endif // QF_ON_CONTEXT_SW

#endif // QF_ON_CONTEXT_SW || Q_SPY</code>
  </operation>
 </package>
 <!--${QK-impl}-->
 <package name="QK-impl" stereotype="0x02">
  <!--${QK-impl::QF_SCHED_STAT_}-->
  <attribute name="QF_SCHED_STAT_" type="" visibility="0x03" properties="0x00">
   <code>QSchedStatus lockStat_;</code>
  </attribute>
  <!--${QK-impl::QF_SCHED_LOCK_}-->
  <operation name="QF_SCHED_LOCK_" type="" visibility="0x03" properties="0x00">
   <!--${QK-impl::QF_SCHED_LOCK_::ceil_}-->
   <parameter name="ceil_" type="std::uint_fast8_t"/>
   <code>do { \
    if (QK_ISR_CONTEXT_()) { \
        lockStat_ = 0xFFU; \
    } else { \
        lockStat_ = QK::schedLock((ceil_)); \
    } \
} while (false)</code>
  </operation>
  <!--${QK-impl::QF_SCHED_UNLOCK_}-->
  <operation name="QF_SCHED_UNLOCK_" type="" visibility="0x03" properties="0x00">
   <code>do { \
    if (lockStat_ != 0xFFU) { \
        QK::schedUnlock(lockStat_); \
    } \
} while (false)</code>
  </operation>
  <!--${QK-impl::QACTIVE_EQUEUE_WAIT_}-->
  <operation name="QACTIVE_EQUEUE_WAIT_" type="" visibility="0x03" properties="0x00">
   <!--${QK-impl::QACTIVE_EQUEUE_W~::me_}-->
   <parameter name="me_" type="QP::QActive *"/>
   <code>(static_cast&lt;void&gt;(0))</code>
  </operation>
  <!--${QK-impl::QACTIVE_EQUEUE_SIGNAL_}-->
  <operation name="QACTIVE_EQUEUE_SIGNAL_?ndef Q_UNSAFE" type="" visibility="0x03" properties="0x00">
   <!--${QK-impl::QACTIVE_EQUEUE_S~::me_}-->
   <parameter name="me_" type="QP::QActive *"/>
   <code>do { \
    QK_priv_.readySet.insert( \
        static_cast&lt;std::uint_fast8_t&gt;((me_)-&gt;m_prio)); \
    QK_priv_.readySet.update_(&amp;QK_priv_.readySet_dis); \
    if (!QK_ISR_CONTEXT_()) { \
        if (QK_sched_() != 0U) { \
            QK_activate_(); \
        } \
    } \
} while (false)</code>
  </operation>
  <!--${QK-impl::QACTIVE_EQUEUE_SIGNAL_}-->
  <operation name="QACTIVE_EQUEUE_SIGNAL_?def Q_UNSAFE" type="" visibility="0x03" properties="0x00">
   <!--${QK-impl::QACTIVE_EQUEUE_S~::me_}-->
   <parameter name="me_" type="QP::QActive *"/>
   <code>do { \
    QK_priv_.readySet.insert( \
        static_cast&lt;std::uint_fast8_t&gt;((me_)-&gt;m_prio)); \
    if (!QK_ISR_CONTEXT_()) { \
        if (QK_sched_() != 0U) { \
            QK_activate_(); \
        } \
    } \
} while (false)</code>
  </operation>
 </package>
 <!--${include}-->
 <directory name="include">
  <!--${include::qp.hpp}-->
  <file name="qp.hpp">
   <text>#ifndef QP_HPP_
#define QP_HPP_

//============================================================================
#define QP_VERSION_STR &quot;8.0.0&quot;
#define QP_VERSION     800U
#define QP_RELEASE     0x7055936FU

//============================================================================
//! @cond INTERNAL

#ifndef Q_SIGNAL_SIZE
#define Q_SIGNAL_SIZE 2U
#endif

#ifndef QF_MAX_ACTIVE
#define QF_MAX_ACTIVE 32U
#endif

#if (QF_MAX_ACTIVE &gt; 64U)
#error QF_MAX_ACTIVE exceeds the maximum of 64U;
#endif

#ifndef QF_MAX_TICK_RATE
#define QF_MAX_TICK_RATE 1U
#endif

#if (QF_MAX_TICK_RATE &gt; 15U)
#error QF_MAX_TICK_RATE exceeds the maximum of 15U;
#endif

#ifndef QF_MAX_EPOOL
#define QF_MAX_EPOOL 3U
#endif

#if (QF_MAX_EPOOL &gt; 15U)
#error QF_MAX_EPOOL exceeds the maximum of 15U;
#endif

#ifndef QF_TIMEEVT_CTR_SIZE
#define QF_TIMEEVT_CTR_SIZE 4U
#endif

#if (QF_TIMEEVT_CTR_SIZE &gt; 4U)
#error QF_TIMEEVT_CTR_SIZE defined incorrectly, expected 1U, 2U, or 4U;
#endif

#ifndef QF_EVENT_SIZ_SIZE
#define QF_EVENT_SIZ_SIZE 2U
#endif

#if (QF_EVENT_SIZ_SIZE &gt; 4U)
#error QF_EVENT_SIZ_SIZE defined incorrectly, expected 1U, 2U, or 4U;
#endif

//! @endcond
//============================================================================

$declare ${glob-types}

$declare ${QEP}

$declare ${QEP-macros}

$declare ${QF::types}

$declare ${QF::QActive}

$declare ${QF::QMActive}

$declare ${QF::QTimeEvt}

$declare ${QF::QTicker}

$declare ${QF::QF-base}

$declare ${QF::QF-dyn}

extern &quot;C&quot; {
$declare ${QF-extern-C}
} // extern &quot;C&quot;

$declare ${QF-macros}

#endif // QP_HPP_</text>
  </file>
  <!--${include::qp_pkg.hpp}-->
  <file name="qp_pkg.hpp">
   <text>#ifndef QP_PKG_HPP_
#define QP_PKG_HPP_

$declare ${QF::QF-pkg}

#define QF_CONST_CAST_(type_, ptr_)    const_cast&lt;type_&gt;(ptr_)
#define Q_PTR2UINT_CAST_(ptr_)         (reinterpret_cast&lt;std::uintptr_t&gt;(ptr_))
#define QF_PTR_RANGE_(x_, min_, max_)  (((min_) &lt;= (x_)) &amp;&amp; ((x_) &lt;= (max_)))

namespace QP {

// Bitmasks are for the QTimeEvt::flags attribute
constexpr std::uint8_t QTE_FLAG_IS_LINKED    {1U &lt;&lt; 7U};
constexpr std::uint8_t QTE_FLAG_WAS_DISARMED {1U &lt;&lt; 6U};

inline void QEvt_refCtr_inc_(QEvt const * const e) noexcept {
    std::uint8_t rc = e-&gt;refCtr_ + 1U;
    (QF_CONST_CAST_(QEvt*, e))-&gt;refCtr_ = rc; // cast away 'const'
#ifndef Q_UNSAFE
    (QF_CONST_CAST_(QEvt*, e))-&gt;evtTag_ = (e-&gt;evtTag_ &amp; 0xF0U) | ((~rc) &amp; 0x0FU);
#endif
}

inline void QEvt_refCtr_dec_(QEvt const * const e) noexcept {
    std::uint8_t rc = e-&gt;refCtr_ - 1U;
    (QF_CONST_CAST_(QEvt*, e))-&gt;refCtr_ = rc; // cast away 'const'
#ifndef Q_UNSAFE
    (QF_CONST_CAST_(QEvt*, e))-&gt;evtTag_ = (e-&gt;evtTag_ &amp; 0xF0U) | ((~rc) &amp; 0x0FU);
#endif
}

} // namespace QP

#endif // QP_PKG_HPP_</text>
  </file>
  <!--${include::qequeue.hpp}-->
  <file name="qequeue.hpp">
   <text>#ifndef QEQUEUE_HPP_
#define QEQUEUE_HPP_

#ifndef QF_EQUEUE_CTR_SIZE
    #define QF_EQUEUE_CTR_SIZE 1U
#endif

namespace QP {

#if (QF_EQUEUE_CTR_SIZE == 1U)
    using QEQueueCtr = std::uint8_t;
#elif (QF_EQUEUE_CTR_SIZE == 2U)
    using QEQueueCtr = std::uint16_t;
#else
    #error &quot;QF_EQUEUE_CTR_SIZE defined incorrectly, expected 1U or 2U&quot;
#endif

class QEvt; // forward declaration

} // namespace QP

$declare ${QF::QEQueue}

#endif // QEQUEUE_HPP_</text>
  </file>
  <!--${include::qmpool.hpp}-->
  <file name="qmpool.hpp">
   <text>#ifndef QMPOOL_HPP_
#define QMPOOL_HPP_

#ifndef QF_MPOOL_SIZ_SIZE
    #define QF_MPOOL_SIZ_SIZE 2U
#endif
#ifndef QF_MPOOL_CTR_SIZE
    #define QF_MPOOL_CTR_SIZE 2U
#endif

namespace QP {

#if (QF_MPOOL_SIZ_SIZE == 1U)
    using QMPoolSize = std::uint8_t;
#elif (QF_MPOOL_SIZ_SIZE == 2U)
    using QMPoolSize = std::uint16_t;
#elif (QF_MPOOL_SIZ_SIZE == 4U)
    using QMPoolSize = std::uint32_t;
#else
    #error &quot;QF_MPOOL_SIZ_SIZE defined incorrectly, expected 1U, 2U, or 4U&quot;
#endif

#if (QF_MPOOL_CTR_SIZE == 1U)
    using QMPoolCtr = std::uint8_t;
#elif (QF_MPOOL_CTR_SIZE == 2U)
    using QMPoolCtr = std::uint16_t;
#elif (QF_MPOOL_CTR_SIZE == 4U)
    using QMPoolCtr = std::uint32_t;
#else
    #error &quot;QF_MPOOL_CTR_SIZE defined incorrectly, expected 1U, 2U, or 4U&quot;
#endif

} // namespace QP

#define QF_MPOOL_EL(evType_) struct { \
    QP::QFreeBlock sto_[((sizeof(evType_) - 1U) / (2U * sizeof(void *))) + 1U]; \
}

$declare ${QF::QFreeBlock}

$declare ${QF::QMPool}

#endif // QMPOOL_HPP_</text>
  </file>
  <!--${include::qv.hpp}-->
  <file name="qv.hpp">
   <text>#ifndef QV_HPP_
#define QV_HPP_

$declare ${QV::QV-base}

//============================================================================
// interface used only for internal implementation, but not in applications
#ifdef QP_IMPL

$declare ${QV-impl}

$declare ${QF_EPOOL-impl}

#endif // QP_IMPL

#endif // QV_HPP_</text>
  </file>
  <!--${include::qk.hpp}-->
  <file name="qk.hpp">
   <text>#ifndef QK_HPP_
#define QK_HPP_

$declare ${QK::QSchedStatus}

$declare ${QK::QK-base}

extern &quot;C&quot; {
$declare ${QK-extern-C}
} // extern &quot;C&quot;

//============================================================================
// interface used only for internal implementation, but not in applications
#ifdef QP_IMPL

$declare ${QK-impl}

$declare ${QF_EPOOL-impl}

#endif // QP_IMPL

#endif // QK_HPP_</text>
  </file>
  <!--${include::qstamp.hpp}-->
  <file name="qstamp.hpp">
   <text>#ifndef QSTAMP_HPP_
#define QSTAMP_HPP_

namespace QP {
extern char const BUILD_DATE[12];
extern char const BUILD_TIME[9];
} // namespace QP

#endif // QSTAMP_HPP_</text>
  </file>
  <!--${include::qpcpp.hpp}-->
  <file name="qpcpp.hpp">
   <text>#ifndef QPCPP_HPP_
#define QPCPP_HPP_

//============================================================================
#include &quot;qp_port.hpp&quot;      // QP port from the port directory
#include &quot;qsafe.h&quot;          // QP Functional Safety (FuSa) Subsystem
#ifdef Q_SPY                // software tracing enabled?
    #include &quot;qs_port.hpp&quot;  // QS/C++ port from the port directory
#else
    #include &quot;qs_dummy.hpp&quot; // QS/C++ dummy (inactive) interface
#endif

//============================================================================
#ifndef QP_API_VERSION
    #define QP_API_VERSION 0
#endif  // QP_API_VERSION

// QP API compatibility layer...
//============================================================================
#if (QP_API_VERSION &lt; 750)

#define QM_SM_STATE_DECL(subm_, state_) error &quot;submachines no longer supported&quot;
#define qm_super_sub(sm_state_) error &quot;submachines no longer supported&quot;
#define qm_tran_ep(tatbl_)      error &quot;submachines no longer supported&quot;
#define qm_tran_xp(xp_, tatbl_) error &quot;submachines no longer supported&quot;
#define qm_sm_exit(sm_state_)   error &quot;submachines no longer supported&quot;

#ifdef QEVT_DYN_CTOR
//! @deprecated #QEVT_DYN_CTOR, please use #QEVT_PAR_INIT
#define QEVT_PAR_INIT
#endif

//! @deprecated plain 'char' is no longer forbidden in MISRA/AUTOSAR-C++
using char_t = char;

//! @deprecated assertion failure handler
//! Use Q_onError() instead.
#define Q_onAssert(module_, id_) Q_onError(module_, id_)

//! @deprecated #Q_NASSERT preprocessor switch to disable QP assertions
#ifdef Q_NASSERT

    // #Q_UNSAFE now replaces the functionality of Q_NASSERT
    #define Q_UNSAFE

    //! @deprecated general purpose assertion with user-specified ID
    //! number that **always** evaluates the `expr_` expression.
    #define Q_ALLEGE_ID(id_, expr_) (static_cast&lt;void&gt;(expr_))

#elif defined Q_UNSAFE

    //! @deprecated general purpose assertion with user-specified ID
    //! number that **always** evaluates the `expr_` expression.
    #define Q_ALLEGE_ID(id_, expr_) (static_cast&lt;void&gt;(expr_))

#else // QP FuSa Subsystem enabled

    //! @deprecated general purpose assertion with user-specified ID
    //! number that **always** evaluates the `expr_` expression.
    //! @note
    //! The use of this macro is no longer recommended.
    #define Q_ALLEGE_ID(id_, expr_) if (!(expr_)) { \
        QF_CRIT_STAT \
        QF_CRIT_ENTRY(); \
        Q_onError(&amp;Q_this_module_[0], (id_)); \
        QF_CRIT_EXIT(); \
    } else ((void)0)

#endif

//! @deprecated general purpose assertion without ID number
//! that **always** evaluates the `expr_` expression.
//! Instead of ID number, this macro is based on the standard
//! `__LINE__` macro.
//!
//! @note The use of this macro is no longer recommended.
#define Q_ALLEGE(expr_)         Q_ALLEGE_ID(__LINE__, (expr_))

//! Static (compile-time) assertion.
//!
//! @deprecated
//! Use Q_ASSERT_STATIC() or better yet `static_assert()` instead.
//!
#define Q_ASSERT_COMPILE(expr_) Q_ASSERT_STATIC(expr_)

//! @deprecated use QP::QF::NO_MARGIN instead
#define QF_NO_MARGIN QP::QF::NO_MARGIN

//============================================================================
#if (QP_API_VERSION &lt; 691)

//! @deprecated enable the QS global filter
#define QS_FILTER_ON(rec_)        QS_GLB_FILTER((rec_))

//! @deprecated disable the QS global filter
#define QS_FILTER_OFF(rec_)       QS_GLB_FILTER(-(rec_))

//! @deprecated enable the QS local filter for SM (state machine) object
#define QS_FILTER_SM_OBJ(obj_)    (static_cast&lt;void&gt;(0))

//! @deprecated enable the QS local filter for AO (active objects)
#define QS_FILTER_AO_OBJ(obj_)    (static_cast&lt;void&gt;(0))

//! @deprecated enable the QS local filter for MP (memory pool) object
#define QS_FILTER_MP_OBJ(obj_)    (static_cast&lt;void&gt;(0))

//! @deprecated enable the QS local filter for EQ (event queue) object
#define QS_FILTER_EQ_OBJ(obj_)    (static_cast&lt;void&gt;(0))

//! @deprecated enable the QS local filter for TE (time event) object
#define QS_FILTER_TE_OBJ(obj_)    (static_cast&lt;void&gt;(0))

#ifdef Q_SPY

//! @deprecated local Filter for a generic application object `obj_`.
#define QS_FILTER_AP_OBJ(obj_) \
    (QP::QS::filt_.loc_AP = (obj_))

//! @deprecated begin of a user QS record, instead use QS_BEGIN_ID()
#define QS_BEGIN(rec_, obj_)                            \
    if (QS_GLB_FILTER_(rec_) &amp;&amp;                         \
        ((QP::QS::filt_.loc[QP::QS::AP_OBJ] == nullptr) \
            || (QP::QS::filt_.loc_AP == (obj_))))       \
    {                                                   \
        QS_CRIT_STAT                                    \
        QS_CRIT_ENTRY();                                \
        QP::QS::beginRec_(static_cast&lt;std::uint_fast8_t&gt;(rec_)); \
        QS_TIME_PRE();

//! @deprecated output hex-formatted std::uint32_t to the QS record
#define QS_U32_HEX(width_, data_)                      \
    (QP::QS::u32_fmt_(static_cast&lt;std::uint8_t&gt;(       \
        (static_cast&lt;std::uint8_t&gt;((width_) &lt;&lt; 4)) | QS_HEX_FMT), (data_)))

#else

#define QS_FILTER_AP_OBJ(obj_)    (static_cast&lt;void&gt;(0))
#define QS_BEGIN(rec_, obj_)      if (false) {
#define QS_U32_HEX(width_, data_) (Q_UNUSED_PAR(0))

#endif // def Q_SPY

//============================================================================
#if (QP_API_VERSION &lt; 680)

//! @deprecated
//! Macro to specify a tran. in the &quot;me-&gt;&quot; impl-strategy.
//! Instead use the new impl-strategy without the &quot;me-&gt;&quot; pointer, where
//! you call tran(Q_STATE_CAST(target_)).
#define Q_TRAN(target_)       (me-&gt;tran(Q_STATE_CAST(target_)))

//! @deprecated
//! Macro to specify a tran-to-history in the &quot;me-&gt;&quot; impl-strategy.
//! Instead use the new impl-strategy without the &quot;me-&gt;&quot; pointer, where
//! you call tran_hist(Q_STATE_CAST(hist_)).
#define Q_TRAN_HIST(hist_)    (me-&gt;tran_hist((hist_)))

//! @deprecated
//! Macro to specify the superstate in the &quot;me-&gt;&quot; impl-strategy.
//! Instead use the new impl-strategy without the &quot;me-&gt;&quot; pointer, where
//! you call super(state_)).
#define Q_SUPER(state_)       (me-&gt;super(Q_STATE_CAST(state_)))

//! @deprecated
//! Macro to call in a QM state entry-handler. Applicable only to QMSMs.
//! Instead use the new impl-strategy without the &quot;me-&gt;&quot; pointer, where
//! the QM-generated code calls qm_entry(Q_STATE_CAST(state_)).
#define QM_ENTRY(state_)      (me-&gt;qm_entry((state_)))

//! @deprecated
//! Macro to call in a QM state exit-handler. Applicable only to QMSMs.
//! Instead use the new impl-strategy without the &quot;me-&gt;&quot; pointer, where
//! the QM-generated code calls qm_exit(Q_STATE_CAST(state_)).
#define QM_EXIT(state_)       (me-&gt;qm_exit((state_)))

//! @deprecated
//! Macro to call in a QM state-handler when it executes a tran.
//! Instead use the new impl-strategy without the &quot;me-&gt;&quot; pointer, where
//! the QM-generated code calls qm_tran((tatbl_)).
#define QM_TRAN(tatbl_)       (me-&gt;qm_tran((tatbl_)))

//! @deprecated
//! Macro to call in a QM state-handler when it executes an initial tran.
//! Instead use the new impl-strategy without the &quot;me-&gt;&quot; pointer, where
//! the QM-generated code calls qm_tran_init((tatbl_)).
#define QM_TRAN_INIT(tatbl_)  (me-&gt;qm_tran_init((tatbl_)))

//! @deprecated
//! Macro to call in a QM state-handler when it executes a tran-to-history.
//! Instead use the new impl-strategy without the &quot;me-&gt;&quot; pointer, where
//! the QM-generated code calls qm_tran_hist((history_), (tatbl_)).
#define QM_TRAN_HIST(history_, tatbl_) \
    (me-&gt;qm_tran_hist((history_), (tatbl_)))

#endif // QP_API_VERSION &lt; 680
#endif // QP_API_VERSION &lt; 691
#endif // QP_API_VERSION &lt; 750

#endif // QPCPP_HPP_</text>
  </file>
 </directory>
 <!--${src}-->
 <directory name="src">
  <!--${src::qf}-->
  <directory name="qf">
   <!--${src::qf::qep_hsm.cpp}-->
   <file name="qep_hsm.cpp">
    <text>#define QP_IMPL             // this is QP implementation
#include &quot;qp_port.hpp&quot;      // QP port
#include &quot;qp_pkg.hpp&quot;       // QP package-scope interface
#include &quot;qsafe.h&quot;          // QP Functional Safety (FuSa) Subsystem
#ifdef Q_SPY                // QS software tracing enabled?
    #include &quot;qs_port.hpp&quot;  // QS port
    #include &quot;qs_pkg.hpp&quot;   // QS facilities for pre-defined trace records
#else
    #include &quot;qs_dummy.hpp&quot; // disable the QS software tracing
#endif // Q_SPY

//============================================================================
//! @cond INTERNAL

// unnamed namespace for local definitions with internal linkage
namespace {
Q_DEFINE_THIS_MODULE(&quot;qep_hsm&quot;)

// immutable events corresponding to the reserved signals.
static QP::QEvt const l_reservedEvt_[4] {
    QP::QEvt(static_cast&lt;QP::QSignal&gt;(QP::QHsm::Q_EMPTY_SIG)),
    QP::QEvt(static_cast&lt;QP::QSignal&gt;(QP::QHsm::Q_ENTRY_SIG)),
    QP::QEvt(static_cast&lt;QP::QSignal&gt;(QP::QHsm::Q_EXIT_SIG)),
    QP::QEvt(static_cast&lt;QP::QSignal&gt;(QP::QHsm::Q_INIT_SIG))
};

// maximum depth of state nesting in a QHsm (including the top level)
// must be &gt;= 3
static constexpr std::int_fast8_t QHSM_MAX_NEST_DEPTH_ {6};

} // unnamed namespace

// helper macro to handle reserved event in an QHsm
#define QHSM_RESERVED_EVT_(state_, sig_) \
    ((*(state_))(this, &amp;l_reservedEvt_[(sig_)]))

// helper macro to trace state entry
#define QS_STATE_ENTRY_(state_, qsId_)         \
    QS_CRIT_ENTRY();                           \
    QS_MEM_SYS();                              \
    QS_BEGIN_PRE(QS_QEP_STATE_ENTRY, (qsId_)) \
        QS_OBJ_PRE(this);                     \
        QS_FUN_PRE(state_);                   \
    QS_END_PRE()                              \
    QS_MEM_APP();                              \
    QS_CRIT_EXIT()

// helper macro to trace state exit
#define QS_STATE_EXIT_(state_, qsId_)          \
    QS_CRIT_ENTRY();                           \
    QS_MEM_SYS();                              \
    QS_BEGIN_PRE(QS_QEP_STATE_EXIT, (qsId_))  \
        QS_OBJ_PRE(this);                     \
        QS_FUN_PRE(state_);                   \
    QS_END_PRE()                              \
    QS_MEM_APP();                              \
    QS_CRIT_EXIT()

//! @endcond

//============================================================================

$define ${QEP::versionStr[]}

$define ${QEP::QHsm}</text>
   </file>
   <!--${src::qf::qep_msm.cpp}-->
   <file name="qep_msm.cpp">
    <text>#define QP_IMPL             // this is QP implementation
#include &quot;qp_port.hpp&quot;      // QP port
#include &quot;qp_pkg.hpp&quot;       // QP package-scope interface
#include &quot;qsafe.h&quot;          // QP Functional Safety (FuSa) Subsystem
#ifdef Q_SPY                // QS software tracing enabled?
    #include &quot;qs_port.hpp&quot;  // QS port
    #include &quot;qs_pkg.hpp&quot;   // QS facilities for pre-defined trace records
#else
    #include &quot;qs_dummy.hpp&quot; // disable the QS software tracing
#endif // Q_SPY

//============================================================================
//! @cond INTERNAL

// unnamed namespace for local definitions with internal linkage
namespace {

Q_DEFINE_THIS_MODULE(&quot;qep_msm&quot;)

// top-state object for QMsm-style state machines
QP::QMState const l_msm_top_s = {
    nullptr,
    nullptr,
    nullptr,
    nullptr,
    nullptr
};

// maximum depth of state nesting in a QMsm (including the top level)
static constexpr std::int_fast8_t QMSM_MAX_NEST_DEPTH_ {8};

// maximum length of transition-action array
static constexpr std::int_fast8_t QMSM_MAX_TRAN_LENGTH_ {2*QMSM_MAX_NEST_DEPTH_};

// maximum depth of entry levels in a MSM for tran. to history.
static constexpr std::int_fast8_t QMSM_MAX_ENTRY_DEPTH_ {4};

} // unnamed namespace

//! @endcond
//============================================================================

$define ${QEP::QMsm}</text>
   </file>
   <!--${src::qf::qf_act.cpp}-->
   <file name="qf_act.cpp">
    <text>#define QP_IMPL             // this is QP implementation
#include &quot;qp_port.hpp&quot;      // QP port
#include &quot;qp_pkg.hpp&quot;       // QP package-scope interface
#include &quot;qsafe.h&quot;          // QP Functional Safety (FuSa) Subsystem
#ifdef Q_SPY                // QS software tracing enabled?
    #include &quot;qs_port.hpp&quot;  // QS port
    #include &quot;qs_pkg.hpp&quot;   // QS facilities for pre-defined trace records
#else
    #include &quot;qs_dummy.hpp&quot; // disable the QS software tracing
#endif // Q_SPY

// unnamed namespace for local definitions with internal linkage
namespace {
//Q_DEFINE_THIS_MODULE(&quot;qf_act&quot;)
} // unnamed namespace

$define ${QF::QActive::registry_[QF_MAX_ACTIVE + 1U]}

$define ${QF::QF-pkg}
$define ${QF::types::QF_LOG2}
#ifndef Q_UNSAFE
$define ${QF::types::QPtrDis}
#endif</text>
   </file>
   <!--${src::qf::qf_actq.cpp}-->
   <file name="qf_actq.cpp">
    <text>#define QP_IMPL             // this is QP implementation
#include &quot;qp_port.hpp&quot;      // QP port
#include &quot;qp_pkg.hpp&quot;       // QP package-scope interface
#include &quot;qsafe.h&quot;          // QP Functional Safety (FuSa) Subsystem
#ifdef Q_SPY                // QS software tracing enabled?
    #include &quot;qs_port.hpp&quot;  // QS port
    #include &quot;qs_pkg.hpp&quot;   // QS facilities for pre-defined trace records
#else
    #include &quot;qs_dummy.hpp&quot; // disable the QS software tracing
#endif // Q_SPY

//============================================================================
// unnamed namespace for local definitions with internal linkage
namespace {
Q_DEFINE_THIS_MODULE(&quot;qf_actq&quot;)
} // unnamed namespace

$define ${QF::QActive::post_}

$define ${QF::QActive::postLIFO}

$define ${QF::QActive::get_}

$define ${QF::QTicker}</text>
   </file>
   <!--${src::qf::qf_defer.cpp}-->
   <file name="qf_defer.cpp">
    <text>#define QP_IMPL             // this is QP implementation
#include &quot;qp_port.hpp&quot;      // QP port
#include &quot;qp_pkg.hpp&quot;       // QP package-scope interface
#include &quot;qsafe.h&quot;          // QP Functional Safety (FuSa) Subsystem
#ifdef Q_SPY                // QS software tracing enabled?
    #include &quot;qs_port.hpp&quot;  // QS port
    #include &quot;qs_pkg.hpp&quot;   // QS facilities for pre-defined trace records
#else
    #include &quot;qs_dummy.hpp&quot; // disable the QS software tracing
#endif // Q_SPY

// unnamed namespace for local definitions with internal linkage
namespace {
Q_DEFINE_THIS_MODULE(&quot;qf_defer&quot;)
} // unnamed namespace

$define ${QF::QActive::defer}

$define ${QF::QActive::recall}

$define ${QF::QActive::flushDeferred}</text>
   </file>
   <!--${src::qf::qf_dyn.cpp}-->
   <file name="qf_dyn.cpp">
    <text>#define QP_IMPL             // this is QP implementation
#include &quot;qp_port.hpp&quot;      // QP port
#include &quot;qp_pkg.hpp&quot;       // QP package-scope interface
#include &quot;qsafe.h&quot;          // QP Functional Safety (FuSa) Subsystem
#ifdef Q_SPY                // QS software tracing enabled?
    #include &quot;qs_port.hpp&quot;  // QS port
    #include &quot;qs_pkg.hpp&quot;   // QS facilities for pre-defined trace records
#else
    #include &quot;qs_dummy.hpp&quot; // disable the QS software tracing
#endif // Q_SPY

#if (QF_MAX_EPOOL &gt; 0U)     // mutable events configured?

// unnamed namespace for local definitions with internal linkage
namespace {
Q_DEFINE_THIS_MODULE(&quot;qf_dyn&quot;)
} // unnamed namespace

$define ${QF::QF-dyn}

#endif // (QF_MAX_EPOOL &gt; 0U) mutable events configured</text>
   </file>
   <!--${src::qf::qf_mem.cpp}-->
   <file name="qf_mem.cpp">
    <text>#define QP_IMPL             // this is QP implementation
#include &quot;qp_port.hpp&quot;      // QP port
#include &quot;qp_pkg.hpp&quot;       // QP package-scope interface
#include &quot;qsafe.h&quot;          // QP Functional Safety (FuSa) Subsystem
#ifdef Q_SPY                // QS software tracing enabled?
    #include &quot;qs_port.hpp&quot;  // QS port
    #include &quot;qs_pkg.hpp&quot;   // QS facilities for pre-defined trace records
#else
    #include &quot;qs_dummy.hpp&quot; // disable the QS software tracing
#endif // Q_SPY

// unnamed namespace for local definitions with internal linkage
namespace {
Q_DEFINE_THIS_MODULE(&quot;qf_mem&quot;)
} // unnamed namespace

$define ${QF::QMPool}</text>
   </file>
   <!--${src::qf::qf_qact.cpp}-->
   <file name="qf_qact.cpp">
    <text>#define QP_IMPL             // this is QP implementation
#include &quot;qp_port.hpp&quot;      // QP port
#include &quot;qp_pkg.hpp&quot;       // QP package-scope interface
#include &quot;qsafe.h&quot;          // QP Functional Safety (FuSa) Subsystem
#ifdef Q_SPY                // QS software tracing enabled?
    #include &quot;qs_port.hpp&quot;  // QS port
    #include &quot;qs_pkg.hpp&quot;   // QS facilities for pre-defined trace records
#else
    #include &quot;qs_dummy.hpp&quot; // disable the QS software tracing
#endif // Q_SPY

// unnamed namespace for local definitions with internal linkage
namespace {
Q_DEFINE_THIS_MODULE(&quot;qf_qact&quot;)
} // unnamed namespace

$define ${QF::QActive::QActive}

$define ${QF::QActive::register_}

$define ${QF::QActive::unregister_}</text>
   </file>
   <!--${src::qf::qf_qmact.cpp}-->
   <file name="qf_qmact.cpp">
    <text>#define QP_IMPL             // this is QP implementation
#include &quot;qp_port.hpp&quot;      // QP port
#include &quot;qp_pkg.hpp&quot;       // QP package-scope interface
#include &quot;qsafe.h&quot;          // QP Functional Safety (FuSa) Subsystem
#ifdef Q_SPY                // QS software tracing enabled?
    #include &quot;qs_port.hpp&quot;  // QS port
    #include &quot;qs_pkg.hpp&quot;   // QS facilities for pre-defined trace records
#else
    #include &quot;qs_dummy.hpp&quot; // disable the QS software tracing
#endif // Q_SPY

// unnamed namespace for local definitions with internal linkage
namespace {
//Q_DEFINE_THIS_MODULE(&quot;qf_qmact&quot;)
} // unnamed namespace

$define ${QF::QMActive}</text>
   </file>
   <!--${src::qf::qf_qeq.cpp}-->
   <file name="qf_qeq.cpp">
    <text>#define QP_IMPL             // this is QP implementation
#include &quot;qp_port.hpp&quot;      // QP port
#include &quot;qp_pkg.hpp&quot;       // QP package-scope interface
#include &quot;qsafe.h&quot;          // QP Functional Safety (FuSa) Subsystem
#ifdef Q_SPY                // QS software tracing enabled?
    #include &quot;qs_port.hpp&quot;  // QS port
    #include &quot;qs_pkg.hpp&quot;   // QS facilities for pre-defined trace records
#else
    #include &quot;qs_dummy.hpp&quot; // disable the QS software tracing
#endif // Q_SPY

// unnamed namespace for local definitions with internal linkage
namespace {
Q_DEFINE_THIS_MODULE(&quot;qf_qeq&quot;)
} // unnamed namespace

$define ${QF::QEQueue}</text>
   </file>
   <!--${src::qf::qf_ps.cpp}-->
   <file name="qf_ps.cpp">
    <text>#define QP_IMPL             // this is QP implementation
#include &quot;qp_port.hpp&quot;      // QP port
#include &quot;qp_pkg.hpp&quot;       // QP package-scope interface
#include &quot;qsafe.h&quot;          // QP Functional Safety (FuSa) Subsystem
#ifdef Q_SPY                // QS software tracing enabled?
    #include &quot;qs_port.hpp&quot;  // QS port
    #include &quot;qs_pkg.hpp&quot;   // QS facilities for pre-defined trace records
#else
    #include &quot;qs_dummy.hpp&quot; // disable the QS software tracing
#endif // Q_SPY

// unnamed namespace for local definitions with internal linkage
namespace {
Q_DEFINE_THIS_MODULE(&quot;qf_ps&quot;)
} // unnamed namespace

$define ${QF::QActive::subscrList_}

$define ${QF::QActive::maxPubSignal_}

$define ${QF::QActive::psInit}

$define ${QF::QActive::publish_}

$define ${QF::QActive::subscribe}

$define ${QF::QActive::unsubscribe}

$define ${QF::QActive::unsubscribeAll}</text>
   </file>
   <!--${src::qf::qf_time.cpp}-->
   <file name="qf_time.cpp">
    <text>#define QP_IMPL             // this is QP implementation
#include &quot;qp_port.hpp&quot;      // QP port
#include &quot;qp_pkg.hpp&quot;       // QP package-scope interface
#include &quot;qsafe.h&quot;          // QP Functional Safety (FuSa) Subsystem
#ifdef Q_SPY                // QS software tracing enabled?
    #include &quot;qs_port.hpp&quot;  // QS port
    #include &quot;qs_pkg.hpp&quot;   // QS facilities for pre-defined trace records
#else
    #include &quot;qs_dummy.hpp&quot; // disable the QS software tracing
#endif // Q_SPY

// unnamed namespace for local definitions with internal linkage
namespace {
Q_DEFINE_THIS_MODULE(&quot;qf_time&quot;)
} // unnamed namespace

$define ${QF::QTimeEvt}</text>
   </file>
  </directory>
  <!--${src::qv}-->
  <directory name="qv">
   <!--${src::qv::qv.cpp}-->
   <file name="qv.cpp">
    <text>#define QP_IMPL             // this is QP implementation
#include &quot;qp_port.hpp&quot;      // QP port
#include &quot;qp_pkg.hpp&quot;       // QP package-scope interface
#include &quot;qsafe.h&quot;          // QP Functional Safety (FuSa) Subsystem
#ifdef Q_SPY                // QS software tracing enabled?
    #include &quot;qs_port.hpp&quot;  // QS port
    #include &quot;qs_pkg.hpp&quot;   // QS facilities for pre-defined trace records
#else
    #include &quot;qs_dummy.hpp&quot; // disable the QS software tracing
#endif // Q_SPY

// protection against including this source file in a wrong project
#ifndef QV_HPP_
    #error &quot;Source file included in a project NOT based on the QV kernel&quot;
#endif // QV_HPP_

// unnamed namespace for local definitions with internal linkage
namespace {
Q_DEFINE_THIS_MODULE(&quot;qv&quot;)
} // unnamed namespace

$define ${QV::QV-base}

$define ${QV::QF-cust}

$define ${QV::QActive}</text>
   </file>
  </directory>
  <!--${src::qk}-->
  <directory name="qk">
   <!--${src::qk::qk.cpp}-->
   <file name="qk.cpp">
    <text>#define QP_IMPL             // this is QP implementation
#include &quot;qp_port.hpp&quot;      // QP port
#include &quot;qp_pkg.hpp&quot;       // QP package-scope interface
#include &quot;qsafe.h&quot;          // QP Functional Safety (FuSa) Subsystem
#ifdef Q_SPY                // QS software tracing enabled?
    #include &quot;qs_port.hpp&quot;  // QS port
    #include &quot;qs_pkg.hpp&quot;   // QS facilities for pre-defined trace records
#else
    #include &quot;qs_dummy.hpp&quot; // disable the QS software tracing
#endif // Q_SPY

// protection against including this source file in a wrong project
#ifndef QK_HPP_
    #error &quot;Source file included in a project NOT based on the QK kernel&quot;
#endif // QK_HPP_

// unnamed namespace for local definitions with internal linkage
namespace {
Q_DEFINE_THIS_MODULE(&quot;qk&quot;)
} // unnamed namespace

$define ${QK::QK-base}

extern &quot;C&quot; {
$define ${QK-extern-C}
} // extern &quot;C&quot;

$define ${QK::QF-cust}

$define ${QK::QActive}</text>
   </file>
  </directory>
  <!--${src::qs}-->
  <directory name="qs">
   <!--${src::qs::qstamp.cpp}-->
   <file name="qstamp.cpp">
    <text>#include &quot;qstamp.hpp&quot;

namespace QP {
char const BUILD_DATE[12] = __DATE__;
char const BUILD_TIME[9] = __TIME__;
} // namespace QP</text>
   </file>
  </directory>
 </directory>
</model>