// ====================================================================== // \title PassiveEventsTesterBase.cpp // \author Generated by fpp-to-cpp // \brief cpp file for PassiveEvents component test harness base class // ====================================================================== #include #include #include "test-base/PassiveEventsTesterBase.hpp" // ---------------------------------------------------------------------- // Component initialization // ---------------------------------------------------------------------- void PassiveEventsTesterBase :: init(NATIVE_INT_TYPE instance) { // Initialize base class Fw::PassiveComponentBase::init(instance); // Connect input port eventOut for ( PlatformIntType port = 0; port < static_cast(this->getNum_from_eventOut()); port++ ) { this->m_from_eventOut[port].init(); this->m_from_eventOut[port].addCallComp( this, from_eventOut_static ); this->m_from_eventOut[port].setPortNum(port); #if FW_OBJECT_NAMES == 1 // The port name consists of this->m_objName and some extra info. // We expect all of this to fit in FW_OBJ_NAME_MAX_SIZE bytes. // However, the compiler may assume that this->m_objName fills // the entire array, whose size is FW_OBJ_NAME_MAX_SIZE. So to // avoid a compiler warning, we provide an extra FW_OBJ_NAME_MAX_SIZE // bytes to cover the extra info. char portName[2*FW_OBJ_NAME_MAX_SIZE]; (void) snprintf( portName, sizeof(portName), "%s_from_eventOut[%" PRI_PlatformIntType "]", this->m_objName, port ); this->m_from_eventOut[port].setObjName(portName); #endif } #if FW_ENABLE_TEXT_LOGGING == 1 // Connect input port textEventOut for ( PlatformIntType port = 0; port < static_cast(this->getNum_from_textEventOut()); port++ ) { this->m_from_textEventOut[port].init(); this->m_from_textEventOut[port].addCallComp( this, from_textEventOut_static ); this->m_from_textEventOut[port].setPortNum(port); #if FW_OBJECT_NAMES == 1 // The port name consists of this->m_objName and some extra info. // We expect all of this to fit in FW_OBJ_NAME_MAX_SIZE bytes. // However, the compiler may assume that this->m_objName fills // the entire array, whose size is FW_OBJ_NAME_MAX_SIZE. So to // avoid a compiler warning, we provide an extra FW_OBJ_NAME_MAX_SIZE // bytes to cover the extra info. char portName[2*FW_OBJ_NAME_MAX_SIZE]; (void) snprintf( portName, sizeof(portName), "%s_from_textEventOut[%" PRI_PlatformIntType "]", this->m_objName, port ); this->m_from_textEventOut[port].setObjName(portName); #endif } #endif // Connect input port timeGetOut for ( PlatformIntType port = 0; port < static_cast(this->getNum_from_timeGetOut()); port++ ) { this->m_from_timeGetOut[port].init(); this->m_from_timeGetOut[port].addCallComp( this, from_timeGetOut_static ); this->m_from_timeGetOut[port].setPortNum(port); #if FW_OBJECT_NAMES == 1 // The port name consists of this->m_objName and some extra info. // We expect all of this to fit in FW_OBJ_NAME_MAX_SIZE bytes. // However, the compiler may assume that this->m_objName fills // the entire array, whose size is FW_OBJ_NAME_MAX_SIZE. So to // avoid a compiler warning, we provide an extra FW_OBJ_NAME_MAX_SIZE // bytes to cover the extra info. char portName[2*FW_OBJ_NAME_MAX_SIZE]; (void) snprintf( portName, sizeof(portName), "%s_from_timeGetOut[%" PRI_PlatformIntType "]", this->m_objName, port ); this->m_from_timeGetOut[port].setObjName(portName); #endif } // Connect input port noArgsOut for ( PlatformIntType port = 0; port < static_cast(this->getNum_from_noArgsOut()); port++ ) { this->m_from_noArgsOut[port].init(); this->m_from_noArgsOut[port].addCallComp( this, from_noArgsOut_static ); this->m_from_noArgsOut[port].setPortNum(port); #if FW_OBJECT_NAMES == 1 // The port name consists of this->m_objName and some extra info. // We expect all of this to fit in FW_OBJ_NAME_MAX_SIZE bytes. // However, the compiler may assume that this->m_objName fills // the entire array, whose size is FW_OBJ_NAME_MAX_SIZE. So to // avoid a compiler warning, we provide an extra FW_OBJ_NAME_MAX_SIZE // bytes to cover the extra info. char portName[2*FW_OBJ_NAME_MAX_SIZE]; (void) snprintf( portName, sizeof(portName), "%s_from_noArgsOut[%" PRI_PlatformIntType "]", this->m_objName, port ); this->m_from_noArgsOut[port].setObjName(portName); #endif } // Connect input port noArgsReturnOut for ( PlatformIntType port = 0; port < static_cast(this->getNum_from_noArgsReturnOut()); port++ ) { this->m_from_noArgsReturnOut[port].init(); this->m_from_noArgsReturnOut[port].addCallComp( this, from_noArgsReturnOut_static ); this->m_from_noArgsReturnOut[port].setPortNum(port); #if FW_OBJECT_NAMES == 1 // The port name consists of this->m_objName and some extra info. // We expect all of this to fit in FW_OBJ_NAME_MAX_SIZE bytes. // However, the compiler may assume that this->m_objName fills // the entire array, whose size is FW_OBJ_NAME_MAX_SIZE. So to // avoid a compiler warning, we provide an extra FW_OBJ_NAME_MAX_SIZE // bytes to cover the extra info. char portName[2*FW_OBJ_NAME_MAX_SIZE]; (void) snprintf( portName, sizeof(portName), "%s_from_noArgsReturnOut[%" PRI_PlatformIntType "]", this->m_objName, port ); this->m_from_noArgsReturnOut[port].setObjName(portName); #endif } // Connect input port typedOut for ( PlatformIntType port = 0; port < static_cast(this->getNum_from_typedOut()); port++ ) { this->m_from_typedOut[port].init(); this->m_from_typedOut[port].addCallComp( this, from_typedOut_static ); this->m_from_typedOut[port].setPortNum(port); #if FW_OBJECT_NAMES == 1 // The port name consists of this->m_objName and some extra info. // We expect all of this to fit in FW_OBJ_NAME_MAX_SIZE bytes. // However, the compiler may assume that this->m_objName fills // the entire array, whose size is FW_OBJ_NAME_MAX_SIZE. So to // avoid a compiler warning, we provide an extra FW_OBJ_NAME_MAX_SIZE // bytes to cover the extra info. char portName[2*FW_OBJ_NAME_MAX_SIZE]; (void) snprintf( portName, sizeof(portName), "%s_from_typedOut[%" PRI_PlatformIntType "]", this->m_objName, port ); this->m_from_typedOut[port].setObjName(portName); #endif } // Connect input port typedReturnOut for ( PlatformIntType port = 0; port < static_cast(this->getNum_from_typedReturnOut()); port++ ) { this->m_from_typedReturnOut[port].init(); this->m_from_typedReturnOut[port].addCallComp( this, from_typedReturnOut_static ); this->m_from_typedReturnOut[port].setPortNum(port); #if FW_OBJECT_NAMES == 1 // The port name consists of this->m_objName and some extra info. // We expect all of this to fit in FW_OBJ_NAME_MAX_SIZE bytes. // However, the compiler may assume that this->m_objName fills // the entire array, whose size is FW_OBJ_NAME_MAX_SIZE. So to // avoid a compiler warning, we provide an extra FW_OBJ_NAME_MAX_SIZE // bytes to cover the extra info. char portName[2*FW_OBJ_NAME_MAX_SIZE]; (void) snprintf( portName, sizeof(portName), "%s_from_typedReturnOut[%" PRI_PlatformIntType "]", this->m_objName, port ); this->m_from_typedReturnOut[port].setObjName(portName); #endif } // Connect output port noArgsGuarded for ( PlatformIntType port = 0; port < static_cast(this->getNum_to_noArgsGuarded()); port++ ) { this->m_to_noArgsGuarded[port].init(); #if FW_OBJECT_NAMES == 1 // The port name consists of this->m_objName and some extra info. // We expect all of this to fit in FW_OBJ_NAME_MAX_SIZE bytes. // However, the compiler may assume that this->m_objName fills // the entire array, whose size is FW_OBJ_NAME_MAX_SIZE. So to // avoid a compiler warning, we provide an extra FW_OBJ_NAME_MAX_SIZE // bytes to cover the extra info. char portName[2*FW_OBJ_NAME_MAX_SIZE]; (void) snprintf( portName, sizeof(portName), "%s_to_noArgsGuarded[%" PRI_PlatformIntType "]", this->m_objName, port ); this->m_to_noArgsGuarded[port].setObjName(portName); #endif } // Connect output port noArgsReturnGuarded for ( PlatformIntType port = 0; port < static_cast(this->getNum_to_noArgsReturnGuarded()); port++ ) { this->m_to_noArgsReturnGuarded[port].init(); #if FW_OBJECT_NAMES == 1 // The port name consists of this->m_objName and some extra info. // We expect all of this to fit in FW_OBJ_NAME_MAX_SIZE bytes. // However, the compiler may assume that this->m_objName fills // the entire array, whose size is FW_OBJ_NAME_MAX_SIZE. So to // avoid a compiler warning, we provide an extra FW_OBJ_NAME_MAX_SIZE // bytes to cover the extra info. char portName[2*FW_OBJ_NAME_MAX_SIZE]; (void) snprintf( portName, sizeof(portName), "%s_to_noArgsReturnGuarded[%" PRI_PlatformIntType "]", this->m_objName, port ); this->m_to_noArgsReturnGuarded[port].setObjName(portName); #endif } // Connect output port noArgsReturnSync for ( PlatformIntType port = 0; port < static_cast(this->getNum_to_noArgsReturnSync()); port++ ) { this->m_to_noArgsReturnSync[port].init(); #if FW_OBJECT_NAMES == 1 // The port name consists of this->m_objName and some extra info. // We expect all of this to fit in FW_OBJ_NAME_MAX_SIZE bytes. // However, the compiler may assume that this->m_objName fills // the entire array, whose size is FW_OBJ_NAME_MAX_SIZE. So to // avoid a compiler warning, we provide an extra FW_OBJ_NAME_MAX_SIZE // bytes to cover the extra info. char portName[2*FW_OBJ_NAME_MAX_SIZE]; (void) snprintf( portName, sizeof(portName), "%s_to_noArgsReturnSync[%" PRI_PlatformIntType "]", this->m_objName, port ); this->m_to_noArgsReturnSync[port].setObjName(portName); #endif } // Connect output port noArgsSync for ( PlatformIntType port = 0; port < static_cast(this->getNum_to_noArgsSync()); port++ ) { this->m_to_noArgsSync[port].init(); #if FW_OBJECT_NAMES == 1 // The port name consists of this->m_objName and some extra info. // We expect all of this to fit in FW_OBJ_NAME_MAX_SIZE bytes. // However, the compiler may assume that this->m_objName fills // the entire array, whose size is FW_OBJ_NAME_MAX_SIZE. So to // avoid a compiler warning, we provide an extra FW_OBJ_NAME_MAX_SIZE // bytes to cover the extra info. char portName[2*FW_OBJ_NAME_MAX_SIZE]; (void) snprintf( portName, sizeof(portName), "%s_to_noArgsSync[%" PRI_PlatformIntType "]", this->m_objName, port ); this->m_to_noArgsSync[port].setObjName(portName); #endif } // Connect output port typedGuarded for ( PlatformIntType port = 0; port < static_cast(this->getNum_to_typedGuarded()); port++ ) { this->m_to_typedGuarded[port].init(); #if FW_OBJECT_NAMES == 1 // The port name consists of this->m_objName and some extra info. // We expect all of this to fit in FW_OBJ_NAME_MAX_SIZE bytes. // However, the compiler may assume that this->m_objName fills // the entire array, whose size is FW_OBJ_NAME_MAX_SIZE. So to // avoid a compiler warning, we provide an extra FW_OBJ_NAME_MAX_SIZE // bytes to cover the extra info. char portName[2*FW_OBJ_NAME_MAX_SIZE]; (void) snprintf( portName, sizeof(portName), "%s_to_typedGuarded[%" PRI_PlatformIntType "]", this->m_objName, port ); this->m_to_typedGuarded[port].setObjName(portName); #endif } // Connect output port typedReturnGuarded for ( PlatformIntType port = 0; port < static_cast(this->getNum_to_typedReturnGuarded()); port++ ) { this->m_to_typedReturnGuarded[port].init(); #if FW_OBJECT_NAMES == 1 // The port name consists of this->m_objName and some extra info. // We expect all of this to fit in FW_OBJ_NAME_MAX_SIZE bytes. // However, the compiler may assume that this->m_objName fills // the entire array, whose size is FW_OBJ_NAME_MAX_SIZE. So to // avoid a compiler warning, we provide an extra FW_OBJ_NAME_MAX_SIZE // bytes to cover the extra info. char portName[2*FW_OBJ_NAME_MAX_SIZE]; (void) snprintf( portName, sizeof(portName), "%s_to_typedReturnGuarded[%" PRI_PlatformIntType "]", this->m_objName, port ); this->m_to_typedReturnGuarded[port].setObjName(portName); #endif } // Connect output port typedReturnSync for ( PlatformIntType port = 0; port < static_cast(this->getNum_to_typedReturnSync()); port++ ) { this->m_to_typedReturnSync[port].init(); #if FW_OBJECT_NAMES == 1 // The port name consists of this->m_objName and some extra info. // We expect all of this to fit in FW_OBJ_NAME_MAX_SIZE bytes. // However, the compiler may assume that this->m_objName fills // the entire array, whose size is FW_OBJ_NAME_MAX_SIZE. So to // avoid a compiler warning, we provide an extra FW_OBJ_NAME_MAX_SIZE // bytes to cover the extra info. char portName[2*FW_OBJ_NAME_MAX_SIZE]; (void) snprintf( portName, sizeof(portName), "%s_to_typedReturnSync[%" PRI_PlatformIntType "]", this->m_objName, port ); this->m_to_typedReturnSync[port].setObjName(portName); #endif } // Connect output port typedSync for ( PlatformIntType port = 0; port < static_cast(this->getNum_to_typedSync()); port++ ) { this->m_to_typedSync[port].init(); #if FW_OBJECT_NAMES == 1 // The port name consists of this->m_objName and some extra info. // We expect all of this to fit in FW_OBJ_NAME_MAX_SIZE bytes. // However, the compiler may assume that this->m_objName fills // the entire array, whose size is FW_OBJ_NAME_MAX_SIZE. So to // avoid a compiler warning, we provide an extra FW_OBJ_NAME_MAX_SIZE // bytes to cover the extra info. char portName[2*FW_OBJ_NAME_MAX_SIZE]; (void) snprintf( portName, sizeof(portName), "%s_to_typedSync[%" PRI_PlatformIntType "]", this->m_objName, port ); this->m_to_typedSync[port].setObjName(portName); #endif } } // ---------------------------------------------------------------------- // Connectors for to ports // ---------------------------------------------------------------------- void PassiveEventsTesterBase :: connect_to_cmdIn( NATIVE_INT_TYPE portNum, Fw::InputCmdPort* port ) { FW_ASSERT( portNum < this->getNum_to_cmdIn(), static_cast(portNum) ); this->m_to_cmdIn[portNum].addCallPort(port); } void PassiveEventsTesterBase :: connect_to_noArgsGuarded( NATIVE_INT_TYPE portNum, Ports::InputNoArgsPort* port ) { FW_ASSERT( portNum < this->getNum_to_noArgsGuarded(), static_cast(portNum) ); this->m_to_noArgsGuarded[portNum].addCallPort(port); } void PassiveEventsTesterBase :: connect_to_noArgsReturnGuarded( NATIVE_INT_TYPE portNum, Ports::InputNoArgsReturnPort* port ) { FW_ASSERT( portNum < this->getNum_to_noArgsReturnGuarded(), static_cast(portNum) ); this->m_to_noArgsReturnGuarded[portNum].addCallPort(port); } void PassiveEventsTesterBase :: connect_to_noArgsReturnSync( NATIVE_INT_TYPE portNum, Ports::InputNoArgsReturnPort* port ) { FW_ASSERT( portNum < this->getNum_to_noArgsReturnSync(), static_cast(portNum) ); this->m_to_noArgsReturnSync[portNum].addCallPort(port); } void PassiveEventsTesterBase :: connect_to_noArgsSync( NATIVE_INT_TYPE portNum, Ports::InputNoArgsPort* port ) { FW_ASSERT( portNum < this->getNum_to_noArgsSync(), static_cast(portNum) ); this->m_to_noArgsSync[portNum].addCallPort(port); } void PassiveEventsTesterBase :: connect_to_typedGuarded( NATIVE_INT_TYPE portNum, Ports::InputTypedPort* port ) { FW_ASSERT( portNum < this->getNum_to_typedGuarded(), static_cast(portNum) ); this->m_to_typedGuarded[portNum].addCallPort(port); } void PassiveEventsTesterBase :: connect_to_typedReturnGuarded( NATIVE_INT_TYPE portNum, Ports::InputTypedReturnPort* port ) { FW_ASSERT( portNum < this->getNum_to_typedReturnGuarded(), static_cast(portNum) ); this->m_to_typedReturnGuarded[portNum].addCallPort(port); } void PassiveEventsTesterBase :: connect_to_typedReturnSync( NATIVE_INT_TYPE portNum, Ports::InputTypedReturnPort* port ) { FW_ASSERT( portNum < this->getNum_to_typedReturnSync(), static_cast(portNum) ); this->m_to_typedReturnSync[portNum].addCallPort(port); } void PassiveEventsTesterBase :: connect_to_typedSync( NATIVE_INT_TYPE portNum, Ports::InputTypedPort* port ) { FW_ASSERT( portNum < this->getNum_to_typedSync(), static_cast(portNum) ); this->m_to_typedSync[portNum].addCallPort(port); } // ---------------------------------------------------------------------- // Getters for from ports // ---------------------------------------------------------------------- Fw::InputCmdRegPort* PassiveEventsTesterBase :: get_from_cmdRegOut(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_from_cmdRegOut(), static_cast(portNum) ); return &this->m_from_cmdRegOut[portNum]; } Fw::InputCmdResponsePort* PassiveEventsTesterBase :: get_from_cmdResponseOut(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_from_cmdResponseOut(), static_cast(portNum) ); return &this->m_from_cmdResponseOut[portNum]; } Fw::InputLogPort* PassiveEventsTesterBase :: get_from_eventOut(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_from_eventOut(), static_cast(portNum) ); return &this->m_from_eventOut[portNum]; } Fw::InputPrmGetPort* PassiveEventsTesterBase :: get_from_prmGetOut(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_from_prmGetOut(), static_cast(portNum) ); return &this->m_from_prmGetOut[portNum]; } Fw::InputPrmSetPort* PassiveEventsTesterBase :: get_from_prmSetOut(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_from_prmSetOut(), static_cast(portNum) ); return &this->m_from_prmSetOut[portNum]; } #if FW_ENABLE_TEXT_LOGGING == 1 Fw::InputLogTextPort* PassiveEventsTesterBase :: get_from_textEventOut(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_from_textEventOut(), static_cast(portNum) ); return &this->m_from_textEventOut[portNum]; } #endif Fw::InputTimePort* PassiveEventsTesterBase :: get_from_timeGetOut(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_from_timeGetOut(), static_cast(portNum) ); return &this->m_from_timeGetOut[portNum]; } Fw::InputTlmPort* PassiveEventsTesterBase :: get_from_tlmOut(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_from_tlmOut(), static_cast(portNum) ); return &this->m_from_tlmOut[portNum]; } Ports::InputNoArgsPort* PassiveEventsTesterBase :: get_from_noArgsOut(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_from_noArgsOut(), static_cast(portNum) ); return &this->m_from_noArgsOut[portNum]; } Ports::InputNoArgsReturnPort* PassiveEventsTesterBase :: get_from_noArgsReturnOut(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_from_noArgsReturnOut(), static_cast(portNum) ); return &this->m_from_noArgsReturnOut[portNum]; } Ports::InputTypedPort* PassiveEventsTesterBase :: get_from_typedOut(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_from_typedOut(), static_cast(portNum) ); return &this->m_from_typedOut[portNum]; } Ports::InputTypedReturnPort* PassiveEventsTesterBase :: get_from_typedReturnOut(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_from_typedReturnOut(), static_cast(portNum) ); return &this->m_from_typedReturnOut[portNum]; } // ---------------------------------------------------------------------- // Component construction and destruction // ---------------------------------------------------------------------- PassiveEventsTesterBase :: PassiveEventsTesterBase( const char* const compName, const U32 maxHistorySize ) : Fw::PassiveComponentBase(compName) { // Initialize port histories this->fromPortHistory_typedOut = new History(maxHistorySize); this->fromPortHistory_typedReturnOut = new History(maxHistorySize); // Initialize event histories #if FW_ENABLE_TEXT_LOGGING this->textLogHistory = new History(maxHistorySize); #endif this->eventHistory_EventActivityLowThrottled = new History(maxHistorySize); this->eventHistory_EventCommand = new History(maxHistorySize); this->eventHistory_EventDiagnostic = new History(maxHistorySize); this->eventHistory_EventFatalThrottled = new History(maxHistorySize); this->eventHistory_EventWarningHigh = new History(maxHistorySize); // Clear history this->clearHistory(); } PassiveEventsTesterBase :: ~PassiveEventsTesterBase() { // Destroy port histories delete this->fromPortHistory_typedOut; delete this->fromPortHistory_typedReturnOut; // Destroy event histories #if FW_ENABLE_TEXT_LOGGING delete this->textLogHistory; #endif delete this->eventHistory_EventActivityLowThrottled; delete this->eventHistory_EventCommand; delete this->eventHistory_EventDiagnostic; delete this->eventHistory_EventFatalThrottled; delete this->eventHistory_EventWarningHigh; } // ---------------------------------------------------------------------- // Handler base-class functions for from ports // ---------------------------------------------------------------------- void PassiveEventsTesterBase :: from_noArgsOut_handlerBase(NATIVE_INT_TYPE portNum) { // Make sure port number is valid FW_ASSERT( portNum < this->getNum_from_noArgsOut(), static_cast(portNum) ); this->from_noArgsOut_handler(portNum); } U32 PassiveEventsTesterBase :: from_noArgsReturnOut_handlerBase(NATIVE_INT_TYPE portNum) { // Make sure port number is valid FW_ASSERT( portNum < this->getNum_from_noArgsReturnOut(), static_cast(portNum) ); return this->from_noArgsReturnOut_handler(portNum); } void PassiveEventsTesterBase :: from_typedOut_handlerBase( NATIVE_INT_TYPE portNum, U32 u32, F32 f32, bool b, const Ports::TypedPortStrings::StringSize80& str1, const E& e, const A& a, const S& s ) { // Make sure port number is valid FW_ASSERT( portNum < this->getNum_from_typedOut(), static_cast(portNum) ); this->from_typedOut_handler( portNum, u32, f32, b, str1, e, a, s ); } F32 PassiveEventsTesterBase :: from_typedReturnOut_handlerBase( NATIVE_INT_TYPE portNum, U32 u32, F32 f32, bool b, const Ports::TypedReturnPortStrings::StringSize80& str2, const E& e, const A& a, const S& s ) { // Make sure port number is valid FW_ASSERT( portNum < this->getNum_from_typedReturnOut(), static_cast(portNum) ); return this->from_typedReturnOut_handler( portNum, u32, f32, b, str2, e, a, s ); } // ---------------------------------------------------------------------- // Invocation functions for to ports // ---------------------------------------------------------------------- void PassiveEventsTesterBase :: invoke_to_noArgsGuarded(NATIVE_INT_TYPE portNum) { // Make sure port number is valid FW_ASSERT( portNum < this->getNum_to_noArgsGuarded(), static_cast(portNum) ); this->m_to_noArgsGuarded[portNum].invoke(); } U32 PassiveEventsTesterBase :: invoke_to_noArgsReturnGuarded(NATIVE_INT_TYPE portNum) { // Make sure port number is valid FW_ASSERT( portNum < this->getNum_to_noArgsReturnGuarded(), static_cast(portNum) ); return this->m_to_noArgsReturnGuarded[portNum].invoke(); } U32 PassiveEventsTesterBase :: invoke_to_noArgsReturnSync(NATIVE_INT_TYPE portNum) { // Make sure port number is valid FW_ASSERT( portNum < this->getNum_to_noArgsReturnSync(), static_cast(portNum) ); return this->m_to_noArgsReturnSync[portNum].invoke(); } void PassiveEventsTesterBase :: invoke_to_noArgsSync(NATIVE_INT_TYPE portNum) { // Make sure port number is valid FW_ASSERT( portNum < this->getNum_to_noArgsSync(), static_cast(portNum) ); this->m_to_noArgsSync[portNum].invoke(); } void PassiveEventsTesterBase :: invoke_to_typedGuarded( NATIVE_INT_TYPE portNum, U32 u32, F32 f32, bool b, const Ports::TypedPortStrings::StringSize80& str1, const E& e, const A& a, const S& s ) { // Make sure port number is valid FW_ASSERT( portNum < this->getNum_to_typedGuarded(), static_cast(portNum) ); this->m_to_typedGuarded[portNum].invoke( u32, f32, b, str1, e, a, s ); } F32 PassiveEventsTesterBase :: invoke_to_typedReturnGuarded( NATIVE_INT_TYPE portNum, U32 u32, F32 f32, bool b, const Ports::TypedReturnPortStrings::StringSize80& str2, const E& e, const A& a, const S& s ) { // Make sure port number is valid FW_ASSERT( portNum < this->getNum_to_typedReturnGuarded(), static_cast(portNum) ); return this->m_to_typedReturnGuarded[portNum].invoke( u32, f32, b, str2, e, a, s ); } F32 PassiveEventsTesterBase :: invoke_to_typedReturnSync( NATIVE_INT_TYPE portNum, U32 u32, F32 f32, bool b, const Ports::TypedReturnPortStrings::StringSize80& str2, const E& e, const A& a, const S& s ) { // Make sure port number is valid FW_ASSERT( portNum < this->getNum_to_typedReturnSync(), static_cast(portNum) ); return this->m_to_typedReturnSync[portNum].invoke( u32, f32, b, str2, e, a, s ); } void PassiveEventsTesterBase :: invoke_to_typedSync( NATIVE_INT_TYPE portNum, U32 u32, F32 f32, bool b, const Ports::TypedPortStrings::StringSize80& str1, const E& e, const A& a, const S& s ) { // Make sure port number is valid FW_ASSERT( portNum < this->getNum_to_typedSync(), static_cast(portNum) ); this->m_to_typedSync[portNum].invoke( u32, f32, b, str1, e, a, s ); } // ---------------------------------------------------------------------- // Getters for port counts // ---------------------------------------------------------------------- NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_to_cmdIn() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_to_cmdIn)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_to_noArgsGuarded() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_to_noArgsGuarded)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_to_noArgsReturnGuarded() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_to_noArgsReturnGuarded)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_to_noArgsReturnSync() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_to_noArgsReturnSync)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_to_noArgsSync() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_to_noArgsSync)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_to_typedGuarded() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_to_typedGuarded)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_to_typedReturnGuarded() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_to_typedReturnGuarded)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_to_typedReturnSync() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_to_typedReturnSync)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_to_typedSync() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_to_typedSync)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_from_cmdRegOut() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_from_cmdRegOut)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_from_cmdResponseOut() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_from_cmdResponseOut)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_from_eventOut() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_from_eventOut)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_from_prmGetOut() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_from_prmGetOut)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_from_prmSetOut() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_from_prmSetOut)); } #if FW_ENABLE_TEXT_LOGGING == 1 NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_from_textEventOut() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_from_textEventOut)); } #endif NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_from_timeGetOut() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_from_timeGetOut)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_from_tlmOut() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_from_tlmOut)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_from_noArgsOut() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_from_noArgsOut)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_from_noArgsReturnOut() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_from_noArgsReturnOut)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_from_typedOut() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_from_typedOut)); } NATIVE_INT_TYPE PassiveEventsTesterBase :: getNum_from_typedReturnOut() const { return static_cast(FW_NUM_ARRAY_ELEMENTS(this->m_from_typedReturnOut)); } // ---------------------------------------------------------------------- // Connection status queries for to ports // ---------------------------------------------------------------------- bool PassiveEventsTesterBase :: isConnected_to_cmdIn(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_to_cmdIn(), static_cast(portNum) ); return this->m_to_cmdIn[portNum].isConnected(); } bool PassiveEventsTesterBase :: isConnected_to_noArgsGuarded(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_to_noArgsGuarded(), static_cast(portNum) ); return this->m_to_noArgsGuarded[portNum].isConnected(); } bool PassiveEventsTesterBase :: isConnected_to_noArgsReturnGuarded(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_to_noArgsReturnGuarded(), static_cast(portNum) ); return this->m_to_noArgsReturnGuarded[portNum].isConnected(); } bool PassiveEventsTesterBase :: isConnected_to_noArgsReturnSync(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_to_noArgsReturnSync(), static_cast(portNum) ); return this->m_to_noArgsReturnSync[portNum].isConnected(); } bool PassiveEventsTesterBase :: isConnected_to_noArgsSync(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_to_noArgsSync(), static_cast(portNum) ); return this->m_to_noArgsSync[portNum].isConnected(); } bool PassiveEventsTesterBase :: isConnected_to_typedGuarded(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_to_typedGuarded(), static_cast(portNum) ); return this->m_to_typedGuarded[portNum].isConnected(); } bool PassiveEventsTesterBase :: isConnected_to_typedReturnGuarded(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_to_typedReturnGuarded(), static_cast(portNum) ); return this->m_to_typedReturnGuarded[portNum].isConnected(); } bool PassiveEventsTesterBase :: isConnected_to_typedReturnSync(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_to_typedReturnSync(), static_cast(portNum) ); return this->m_to_typedReturnSync[portNum].isConnected(); } bool PassiveEventsTesterBase :: isConnected_to_typedSync(NATIVE_INT_TYPE portNum) { FW_ASSERT( portNum < this->getNum_to_typedSync(), static_cast(portNum) ); return this->m_to_typedSync[portNum].isConnected(); } // ---------------------------------------------------------------------- // Functions for testing events // ---------------------------------------------------------------------- void PassiveEventsTesterBase :: dispatchEvents( FwEventIdType id, const Fw::Time& timeTag, const Fw::LogSeverity severity, Fw::LogBuffer& args ) { args.resetDeser(); const U32 idBase = this->getIdBase(); FW_ASSERT(id >= idBase, id, idBase); switch (id - idBase) { case PassiveEventsComponentBase::EVENTID_EVENTACTIVITYHIGH: { #if FW_AMPCS_COMPATIBLE // For AMPCS, decode zero arguments Fw::SerializeStatus _zero_status = Fw::FW_SERIALIZE_OK; U8 _noArgs; _zero_status = args.deserialize(_noArgs); FW_ASSERT( _zero_status == Fw::FW_SERIALIZE_OK, static_cast(_zero_status) ); #endif this->logIn_ACTIVITY_HI_EventActivityHigh(); break; } case PassiveEventsComponentBase::EVENTID_EVENTACTIVITYLOWTHROTTLED: { Fw::SerializeStatus _status = Fw::FW_SERIALIZE_OK; #if FW_AMPCS_COMPATIBLE // Deserialize the number of arguments. U8 _numArgs; _status = args.deserialize(_numArgs); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); // Verify they match expected. FW_ASSERT(_numArgs == 3, _numArgs, 3); #endif U32 u32; #if FW_AMPCS_COMPATIBLE { // Deserialize the argument size U8 _argSize; _status = args.deserialize(_argSize); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); FW_ASSERT(_argSize == sizeof(U32), _argSize, sizeof(U32)); } #endif _status = args.deserialize(u32); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); F32 f32; #if FW_AMPCS_COMPATIBLE { // Deserialize the argument size U8 _argSize; _status = args.deserialize(_argSize); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); FW_ASSERT(_argSize == sizeof(F32), _argSize, sizeof(F32)); } #endif _status = args.deserialize(f32); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); bool b; #if FW_AMPCS_COMPATIBLE { // Deserialize the argument size U8 _argSize; _status = args.deserialize(_argSize); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); FW_ASSERT(_argSize == sizeof(U8), _argSize, sizeof(U8)); } #endif _status = args.deserialize(b); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); this->logIn_ACTIVITY_LO_EventActivityLowThrottled(u32, f32, b); break; } case PassiveEventsComponentBase::EVENTID_EVENTCOMMAND: { Fw::SerializeStatus _status = Fw::FW_SERIALIZE_OK; #if FW_AMPCS_COMPATIBLE // Deserialize the number of arguments. U8 _numArgs; _status = args.deserialize(_numArgs); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); // Verify they match expected. FW_ASSERT(_numArgs == 2, _numArgs, 2); #endif Fw::LogStringArg str1; #if FW_AMPCS_COMPATIBLE { // Deserialize the argument size U8 _argSize; _status = args.deserialize(_argSize); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); FW_ASSERT(_argSize == Fw::LogStringArg::SERIALIZED_SIZE, _argSize, Fw::LogStringArg::SERIALIZED_SIZE); } #endif _status = args.deserialize(str1); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); Fw::LogStringArg str2; #if FW_AMPCS_COMPATIBLE { // Deserialize the argument size U8 _argSize; _status = args.deserialize(_argSize); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); FW_ASSERT(_argSize == Fw::LogStringArg::SERIALIZED_SIZE, _argSize, Fw::LogStringArg::SERIALIZED_SIZE); } #endif _status = args.deserialize(str2); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); this->logIn_COMMAND_EventCommand(str1, str2); break; } case PassiveEventsComponentBase::EVENTID_EVENTDIAGNOSTIC: { Fw::SerializeStatus _status = Fw::FW_SERIALIZE_OK; #if FW_AMPCS_COMPATIBLE // Deserialize the number of arguments. U8 _numArgs; _status = args.deserialize(_numArgs); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); // Verify they match expected. FW_ASSERT(_numArgs == 1, _numArgs, 1); #endif E e; #if FW_AMPCS_COMPATIBLE { // Deserialize the argument size U8 _argSize; _status = args.deserialize(_argSize); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); FW_ASSERT(_argSize == E::SERIALIZED_SIZE, _argSize, E::SERIALIZED_SIZE); } #endif _status = args.deserialize(e); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); this->logIn_DIAGNOSTIC_EventDiagnostic(e); break; } case PassiveEventsComponentBase::EVENTID_EVENTFATALTHROTTLED: { Fw::SerializeStatus _status = Fw::FW_SERIALIZE_OK; #if FW_AMPCS_COMPATIBLE // Deserialize the number of arguments. U8 _numArgs; _status = args.deserialize(_numArgs); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); // Verify they match expected. FW_ASSERT(_numArgs == 1 + 1, _numArgs, 1 + 1); // For FATAL, there is a stack size of 4 and a dummy entry U8 stackArgLen; _status = args.deserialize(stackArgLen); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); FW_ASSERT(stackArgLen == 4, stackArgLen); U32 dummyStackArg; _status = args.deserialize(dummyStackArg); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); FW_ASSERT(dummyStackArg == 0, dummyStackArg); #endif A a; #if FW_AMPCS_COMPATIBLE { // Deserialize the argument size U8 _argSize; _status = args.deserialize(_argSize); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); FW_ASSERT(_argSize == A::SERIALIZED_SIZE, _argSize, A::SERIALIZED_SIZE); } #endif _status = args.deserialize(a); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); this->logIn_FATAL_EventFatalThrottled(a); break; } case PassiveEventsComponentBase::EVENTID_EVENTWARNINGHIGH: { Fw::SerializeStatus _status = Fw::FW_SERIALIZE_OK; #if FW_AMPCS_COMPATIBLE // Deserialize the number of arguments. U8 _numArgs; _status = args.deserialize(_numArgs); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); // Verify they match expected. FW_ASSERT(_numArgs == 1, _numArgs, 1); #endif S s; #if FW_AMPCS_COMPATIBLE { // Deserialize the argument size U8 _argSize; _status = args.deserialize(_argSize); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); FW_ASSERT(_argSize == S::SERIALIZED_SIZE, _argSize, S::SERIALIZED_SIZE); } #endif _status = args.deserialize(s); FW_ASSERT( _status == Fw::FW_SERIALIZE_OK, static_cast(_status) ); this->logIn_WARNING_HI_EventWarningHigh(s); break; } case PassiveEventsComponentBase::EVENTID_EVENTWARNINGLOWTHROTTLED: { #if FW_AMPCS_COMPATIBLE // For AMPCS, decode zero arguments Fw::SerializeStatus _zero_status = Fw::FW_SERIALIZE_OK; U8 _noArgs; _zero_status = args.deserialize(_noArgs); FW_ASSERT( _zero_status == Fw::FW_SERIALIZE_OK, static_cast(_zero_status) ); #endif this->logIn_WARNING_LO_EventWarningLowThrottled(); break; } default: { FW_ASSERT(0, id); break; } } } #if FW_ENABLE_TEXT_LOGGING void PassiveEventsTesterBase :: textLogIn( FwEventIdType id, const Fw::Time& timeTag, const Fw::LogSeverity severity, const Fw::TextLogString& text ) { TextLogEntry e = { id, timeTag, severity, text }; textLogHistory->push_back(e); } #endif void PassiveEventsTesterBase :: logIn_ACTIVITY_HI_EventActivityHigh() { this->eventsSize_EventActivityHigh++; this->eventsSize++; } void PassiveEventsTesterBase :: logIn_ACTIVITY_LO_EventActivityLowThrottled( U32 u32, F32 f32, bool b ) { EventEntry_EventActivityLowThrottled _e = { u32, f32, b }; eventHistory_EventActivityLowThrottled->push_back(_e); this->eventsSize++; } void PassiveEventsTesterBase :: logIn_COMMAND_EventCommand( const Fw::LogStringArg& str1, const Fw::LogStringArg& str2 ) { EventEntry_EventCommand _e = { str1, str2 }; eventHistory_EventCommand->push_back(_e); this->eventsSize++; } void PassiveEventsTesterBase :: logIn_DIAGNOSTIC_EventDiagnostic(E e) { EventEntry_EventDiagnostic _e = { e }; eventHistory_EventDiagnostic->push_back(_e); this->eventsSize++; } void PassiveEventsTesterBase :: logIn_FATAL_EventFatalThrottled(A a) { EventEntry_EventFatalThrottled _e = { a }; eventHistory_EventFatalThrottled->push_back(_e); this->eventsSize++; } void PassiveEventsTesterBase :: logIn_WARNING_HI_EventWarningHigh(S s) { EventEntry_EventWarningHigh _e = { s }; eventHistory_EventWarningHigh->push_back(_e); this->eventsSize++; } void PassiveEventsTesterBase :: logIn_WARNING_LO_EventWarningLowThrottled() { this->eventsSize_EventWarningLowThrottled++; this->eventsSize++; } // ---------------------------------------------------------------------- // Functions to test time // ---------------------------------------------------------------------- void PassiveEventsTesterBase :: setTestTime(const Fw::Time& timeTag) { this->m_testTime = timeTag; } // ---------------------------------------------------------------------- // History functions // ---------------------------------------------------------------------- void PassiveEventsTesterBase :: clearHistory() { this->clearFromPortHistory(); #if FW_ENABLE_TEXT_LOGGING this->textLogHistory->clear(); #endif this->clearEvents(); } void PassiveEventsTesterBase :: clearFromPortHistory() { this->fromPortHistorySize = 0; this->fromPortHistorySize_noArgsOut = 0; this->fromPortHistorySize_noArgsReturnOut = 0; this->fromPortHistory_typedOut->clear(); this->fromPortHistory_typedReturnOut->clear(); } void PassiveEventsTesterBase :: pushFromPortEntry_noArgsOut() { this->fromPortHistorySize_noArgsOut++; this->fromPortHistorySize++; } void PassiveEventsTesterBase :: pushFromPortEntry_noArgsReturnOut() { this->fromPortHistorySize_noArgsReturnOut++; this->fromPortHistorySize++; } void PassiveEventsTesterBase :: pushFromPortEntry_typedOut( U32 u32, F32 f32, bool b, const Ports::TypedPortStrings::StringSize80& str1, const E& e, const A& a, const S& s ) { FromPortEntry_typedOut _e = { u32, f32, b, str1, e, a, s }; this->fromPortHistory_typedOut->push_back(_e); this->fromPortHistorySize++; } void PassiveEventsTesterBase :: pushFromPortEntry_typedReturnOut( U32 u32, F32 f32, bool b, const Ports::TypedReturnPortStrings::StringSize80& str2, const E& e, const A& a, const S& s ) { FromPortEntry_typedReturnOut _e = { u32, f32, b, str2, e, a, s }; this->fromPortHistory_typedReturnOut->push_back(_e); this->fromPortHistorySize++; } void PassiveEventsTesterBase :: clearEvents() { this->eventsSize = 0; this->eventsSize_EventActivityHigh = 0; this->eventHistory_EventActivityLowThrottled->clear(); this->eventHistory_EventCommand->clear(); this->eventHistory_EventDiagnostic->clear(); this->eventHistory_EventFatalThrottled->clear(); this->eventHistory_EventWarningHigh->clear(); this->eventsSize_EventWarningLowThrottled = 0; } #if FW_ENABLE_TEXT_LOGGING void PassiveEventsTesterBase :: printTextLogHistoryEntry( const TextLogEntry& e, FILE* file ) { const char* severityString = "UNKNOWN"; switch (e.severity.e) { case Fw::LogSeverity::FATAL: severityString = "FATAL"; break; case Fw::LogSeverity::WARNING_HI: severityString = "WARNING_HI"; break; case Fw::LogSeverity::WARNING_LO: severityString = "WARNING_LO"; break; case Fw::LogSeverity::COMMAND: severityString = "COMMAND"; break; case Fw::LogSeverity::ACTIVITY_HI: severityString = "ACTIVITY_HI"; break; case Fw::LogSeverity::ACTIVITY_LO: severityString = "ACTIVITY_LO"; break; case Fw::LogSeverity::DIAGNOSTIC: severityString = "DIAGNOSTIC"; break; default: severityString = "SEVERITY ERROR"; break; } fprintf( file, "EVENT: (%" PRI_FwEventIdType ") (%" PRI_FwTimeBaseStoreType ":%" PRIu32 ",%" PRIu32 ") %s: %s\n", e.id, static_cast(e.timeTag.getTimeBase()), e.timeTag.getSeconds(), e.timeTag.getUSeconds(), severityString, e.text.toChar() ); } void PassiveEventsTesterBase :: printTextLogHistory(FILE* const file) { for (U32 i = 0; i < this->textLogHistory->size(); i++) { this->printTextLogHistoryEntry( this->textLogHistory->at(i), file ); } } #endif // ---------------------------------------------------------------------- // Static functions for output ports // ---------------------------------------------------------------------- void PassiveEventsTesterBase :: from_eventOut_static( Fw::PassiveComponentBase* const callComp, NATIVE_INT_TYPE portNum, FwEventIdType id, Fw::Time& timeTag, const Fw::LogSeverity& severity, Fw::LogBuffer& args ) { PassiveEventsTesterBase* _testerBase = static_cast(callComp); _testerBase->dispatchEvents(id, timeTag, severity, args); } #if FW_ENABLE_TEXT_LOGGING == 1 void PassiveEventsTesterBase :: from_textEventOut_static( Fw::PassiveComponentBase* const callComp, NATIVE_INT_TYPE portNum, FwEventIdType id, Fw::Time& timeTag, const Fw::LogSeverity& severity, Fw::TextLogString& text ) { PassiveEventsTesterBase* _testerBase = static_cast(callComp); _testerBase->textLogIn(id, timeTag, severity, text); } #endif void PassiveEventsTesterBase :: from_timeGetOut_static( Fw::PassiveComponentBase* const callComp, NATIVE_INT_TYPE portNum, Fw::Time& time ) { PassiveEventsTesterBase* _testerBase = static_cast(callComp); time = _testerBase->m_testTime; } void PassiveEventsTesterBase :: from_noArgsOut_static( Fw::PassiveComponentBase* const callComp, NATIVE_INT_TYPE portNum ) { FW_ASSERT(callComp != nullptr); PassiveEventsTesterBase* _testerBase = static_cast(callComp); _testerBase->from_noArgsOut_handlerBase(portNum); } U32 PassiveEventsTesterBase :: from_noArgsReturnOut_static( Fw::PassiveComponentBase* const callComp, NATIVE_INT_TYPE portNum ) { FW_ASSERT(callComp != nullptr); PassiveEventsTesterBase* _testerBase = static_cast(callComp); return _testerBase->from_noArgsReturnOut_handlerBase(portNum); } void PassiveEventsTesterBase :: from_typedOut_static( Fw::PassiveComponentBase* const callComp, NATIVE_INT_TYPE portNum, U32 u32, F32 f32, bool b, const Ports::TypedPortStrings::StringSize80& str1, const E& e, const A& a, const S& s ) { FW_ASSERT(callComp != nullptr); PassiveEventsTesterBase* _testerBase = static_cast(callComp); _testerBase->from_typedOut_handlerBase( portNum, u32, f32, b, str1, e, a, s ); } F32 PassiveEventsTesterBase :: from_typedReturnOut_static( Fw::PassiveComponentBase* const callComp, NATIVE_INT_TYPE portNum, U32 u32, F32 f32, bool b, const Ports::TypedReturnPortStrings::StringSize80& str2, const E& e, const A& a, const S& s ) { FW_ASSERT(callComp != nullptr); PassiveEventsTesterBase* _testerBase = static_cast(callComp); return _testerBase->from_typedReturnOut_handlerBase( portNum, u32, f32, b, str2, e, a, s ); }