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/**
* @file JARTStateMachineGAM.cpp
* @brief Source file for class JARTStateMachineGAM
* @date Nov 26, 2018
* @author aneto
*
* @copyright Copyright 2015 F4E | European Joint Undertaking for ITER and
* the Development of Fusion Energy ('Fusion for Energy').
* Licensed under the EUPL, Version 1.1 or - as soon they will be approved
* by the European Commission - subsequent versions of the EUPL (the "Licence")
* You may not use this work except in compliance with the Licence.
* You may obtain a copy of the Licence at: http://ec.europa.eu/idabc/eupl
*
* @warning Unless required by applicable law or agreed to in writing,
* software distributed under the Licence is distributed on an "AS IS"
* basis, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express
* or implied. See the Licence permissions and limitations under the Licence.
* @details This source file contains the definition of all the methods for
* the class JARTStateMachineGAM (public, protected, and private). Be aware that some
* methods, such as those inline could be defined on the header file, instead.
*/
/*---------------------------------------------------------------------------*/
/* Standard header includes */
/*---------------------------------------------------------------------------*/
/*---------------------------------------------------------------------------*/
/* Project header includes */
/*---------------------------------------------------------------------------*/
#include "JARTStateMachineGAM.h"
#include "AdvancedErrorManagement.h"
/*---------------------------------------------------------------------------*/
/* Static definitions */
/*---------------------------------------------------------------------------*/
static MARTe::uint64 getCurrentTimeUs() {
using namespace MARTe;
return static_cast<uint64>(HighResolutionTimer::Counter() * HighResolutionTimer::Period() * 1e6f + 0.5f);
}
/*---------------------------------------------------------------------------*/
/* Method definitions */
/*---------------------------------------------------------------------------*/
JARTStateMachineGAM::JARTStateMachineGAM() {
currentState = WaitTrigger; // Set Entry state.
plcOnTime = 0; // Triggered time holder.
//Output and condition in a given state.
conditionTrigger = 1;
aps_hvon = 0;
aps_swon = 0;
bps_hvon = 0;
bps_swon = 0;
mhvps_hvon = 0;
// Parameters which get from Input signals.
triggerSignal = NULL_PTR(MARTe::uint32 *);
currentTime = NULL_PTR(MARTe::uint32 *);
turn_off_delay = 2000; //us
triggerDelay_mhvps_hvon = NULL_PTR(MARTe::uint32 *);
triggerDelay_aps_hvon = NULL_PTR(MARTe::uint32 *);
triggerDelay_aps_swon = NULL_PTR(MARTe::uint32 *);
triggerDelay_bps_hvon = NULL_PTR(MARTe::uint32 *);
triggerDelay_bps_swon = NULL_PTR(MARTe::uint32 *);
triggerDelay_shotlen = NULL_PTR(MARTe::uint32 *);
stopRequest = NULL_PTR(MARTe::uint32 *);
modePulseLengthLimit = NULL_PTR(MARTe::uint32 *);
short_pulse_mode = NULL_PTR(MARTe::uint32 *);
modulation = NULL_PTR(MARTe::uint32 *);
// write out target.
outputSignal = NULL_PTR(MARTe::uint32 *);
outputBeamON = NULL_PTR(MARTe::uint32 *);
outputHVArmed = NULL_PTR(MARTe::uint32 *);
outputHVInjection = NULL_PTR(MARTe::uint32 *);
outputRFON = NULL_PTR(MARTe::uint32 *);
outputBeamONTime = NULL_PTR(MARTe::uint32 *);
outputRFONTime = NULL_PTR(MARTe::uint32 *);
shotCounter = NULL_PTR(MARTe::uint32 *);
mhvps_hvon_is_on = false;
aps_hvon_is_on = false;
aps_swon_is_on = false;
bps_hvon_is_on = false;
bps_swon_is_on = false;
apsSwonHighResolutionTime = 0;
aps_hvon_state=0;
aps_swon_state=0;
mhvps_hvon_state=0;
bps_hvon_state=0;
bps_swon_state=0;
}
JARTStateMachineGAM::~JARTStateMachineGAM() {
}
bool JARTStateMachineGAM::Initialise(MARTe::StructuredDataI & data) {
using namespace MARTe;
bool ok = GAM::Initialise(data);
if (ok) {
ok = data.Read("ConditionTrigger", conditionTrigger);
if (!ok) {
REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "The Condition1 shall be specified");
}
}
if (ok) {
ok = data.Read("mhvps_hvon", mhvps_hvon);
if (!ok) {
REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "The mhvps_hvon shall be specified");
}
}
if (ok) {
ok = data.Read("aps_hvon", aps_hvon);
if (!ok) {
REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "The aps_hvon shall be specified");
}
}
if (ok) {
ok = data.Read("aps_swon", aps_swon);
if (!ok) {
REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "The aps_swon shall be specified");
}
}
if (ok) {
ok = data.Read("bps_hvon", bps_hvon);
if (!ok) {
REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "The bps_hvon shall be specified");
}
}
if (ok) {
ok = data.Read("bps_swon", bps_swon);
if (!ok) {
REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "The bps_swon shall be specified");
}
}
return ok;
}
bool JARTStateMachineGAM::PrepareNextState(const MARTe::char8 * const currentStateName, const MARTe::char8 * const nextStateName) {
return true;
}
bool JARTStateMachineGAM::Setup() {
using namespace MARTe;
bool ok = (numberOfInputSignals == 12u);
if (ok) {
ok = (numberOfOutputSignals == 16u);
if (!ok) {
REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "Seven output signals shall be defined %d",numberOfOutputSignals);
}
}
else {
REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "Nine input signals shall be defined");
}
if (ok) {
uint32 c;
for (c = 0u; c < numberOfInputSignals; c++) {
TypeDescriptor inputType = GetSignalType(InputSignals, c);
ok = (inputType == UnsignedInteger32Bit);
if (!ok) {
StreamString signalName;
(void) GetSignalName(InputSignals, c, signalName);
REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "Signal %s shall be defined as uint32", signalName.Buffer());
}
}
}
if (ok) {
uint32 c;
for (c = 0u; c < numberOfOutputSignals; c++) {
TypeDescriptor outputType = GetSignalType(OutputSignals, c);
ok = (outputType == UnsignedInteger32Bit || outputType == UnsignedInteger8Bit);
if (!ok) {
StreamString signalName;
(void) GetSignalName(InputSignals, c, signalName);
REPORT_ERROR(MARTe::ErrorManagement::ParametersError, "Signal %s shall be defined as uint32", signalName.Buffer());
}
}
}
if (ok) {
currentTime = reinterpret_cast<uint32 *>(GetInputSignalMemory(0));
triggerSignal = reinterpret_cast<uint32 *>(GetInputSignalMemory(1));
triggerDelay_mhvps_hvon = reinterpret_cast<uint32 *>(GetInputSignalMemory(2));
triggerDelay_aps_hvon = reinterpret_cast<uint32 *>(GetInputSignalMemory(3));
triggerDelay_aps_swon = reinterpret_cast<uint32 *>(GetInputSignalMemory(4));
triggerDelay_bps_hvon = reinterpret_cast<uint32 *>(GetInputSignalMemory(5));
triggerDelay_bps_swon = reinterpret_cast<uint32 *>(GetInputSignalMemory(6));
triggerDelay_shotlen = reinterpret_cast<uint32 *>(GetInputSignalMemory(7));
stopRequest = reinterpret_cast<uint32 *>(GetInputSignalMemory(8));
modePulseLengthLimit = reinterpret_cast<uint32 *>(GetInputSignalMemory(9));
short_pulse_mode = reinterpret_cast<uint32 *>(GetInputSignalMemory(10));
modulation = reinterpret_cast<uint32 *>(GetInputSignalMemory(11));
outputSignal = reinterpret_cast<uint32 *>(GetOutputSignalMemory(0));
outputBeamON = reinterpret_cast<uint32 *>(GetOutputSignalMemory(1));
outputHVArmed = reinterpret_cast<uint32 *>(GetOutputSignalMemory(2));
outputHVInjection = reinterpret_cast<uint32 *>(GetOutputSignalMemory(3));
outputRFON = reinterpret_cast<uint32 *>(GetOutputSignalMemory(4));
outputBeamONTime = reinterpret_cast<uint32 *>(GetOutputSignalMemory(5));
outputRFONTime = reinterpret_cast<uint32 *>(GetOutputSignalMemory(6));
shotCounter = reinterpret_cast<uint32 *>(GetOutputSignalMemory(7));
outputAPSHVON = reinterpret_cast<uint32 *>(GetOutputSignalMemory(8));
outputAPSSWON = reinterpret_cast<uint32 *>(GetOutputSignalMemory(9));
outputBPSHVON = reinterpret_cast<uint32 *>(GetOutputSignalMemory(10));
outputBPSSWON = reinterpret_cast<uint32 *>(GetOutputSignalMemory(11));
outputMHVPSON = reinterpret_cast<uint32 *>(GetOutputSignalMemory(12));
outputSignalNI6259 = reinterpret_cast<uint32 *>(GetOutputSignalMemory(13));
outputSignalNI6528P3 = reinterpret_cast<uint8 *>(GetOutputSignalMemory(14));
outputSignalNI6528P4 = reinterpret_cast<uint8 *>(GetOutputSignalMemory(15));
*shotCounter = 0;
}
return ok;
}
bool JARTStateMachineGAM::Execute() {
using namespace MARTe;
if (currentState == WaitTrigger) {
//State Transition condition
if ((*triggerSignal == conditionTrigger)) {
//REPORT_ERROR(ErrorManagement::Debug, "Start beam-on sequence at %d.", *currentTime);
plcOnTime = *currentTime; //Save pulse start time.
//*outputBeamON = 0;
//State transition.
currentState = SwitchingHVPS;
}
}
else if (currentState == SwitchingHVPS) {
//Actions in this state.
if (*stopRequest != 0 || *triggerSignal != conditionTrigger) {
*outputSignal = 0;
currentState = HVTerminate;
}
if (*currentTime >= (plcOnTime + *triggerDelay_bps_hvon) && bps_hvon_is_on == false){
//Do action
*outputSignal += bps_hvon;
bps_hvon_is_on = true; bps_hvon_state=1;
//REPORT_ERROR(ErrorManagement::Debug, "bps_hvon was set to outputSignal at %d.", *currentTime);
*outputBPSHVON=1;
}
if (*currentTime >= (plcOnTime + *triggerDelay_aps_hvon) && aps_hvon_is_on == false) {
//Do action
*outputSignal += aps_hvon;
aps_hvon_is_on = true; aps_hvon_state=1;
//REPORT_ERROR(ErrorManagement::Debug, "aps_hvon was set to outputSignal at %d.", *currentTime);
*outputAPSHVON=1;
}
if (*currentTime >= (plcOnTime + *triggerDelay_bps_swon) && bps_swon_is_on==false){
//Do action
*outputSignal += bps_swon;
bps_swon_is_on = true; bps_swon_state=1;
//REPORT_ERROR(ErrorManagement::Debug, "bps_swon was set to outputSignal at %d.", *currentTime);
*outputBPSSWON=1;
}
if (*currentTime >= (plcOnTime + *triggerDelay_mhvps_hvon) && mhvps_hvon_is_on==false) {
//Do action
*outputSignal += mhvps_hvon;
mhvps_hvon_is_on = true; mhvps_hvon_state=1;
//REPORT_ERROR(ErrorManagement::Debug, "mhvps_hvon was set to outputSignal at %d.", *currentTime);
*outputMHVPSON=1;
}
if (bps_swon_is_on && mhvps_hvon_is_on && *currentTime >= (plcOnTime + *triggerDelay_aps_swon)){
//Do action
*outputSignal += aps_swon;
aps_swon_is_on = true; aps_swon_state=1;
apsSwonHighResolutionTime = getCurrentTimeUs();
apsSwonTime = *currentTime;
//REPORT_ERROR(ErrorManagement::Debug, "aps_swon was set to outputSignal at %d.", *currentTime);
*outputAPSSWON=1;
}
*outputBeamONTime = *currentTime - plcOnTime; //Save RFON start time.
if (bps_hvon_is_on && aps_hvon_is_on){
*outputHVArmed = 1;
}
if (bps_swon_is_on || mhvps_hvon_is_on){
*outputHVInjection = 1;
}
//State transition condition
if (aps_swon_is_on){
currentState = RFON;
*outputRFON = 0;
*outputBeamON = 1;
*shotCounter += 1;
//REPORT_ERROR(ErrorManagement::Debug, "state was changed to RFON");
}
}
else if (currentState == RFON) {
//Action in this state.
if (*stopRequest != 0 || *triggerSignal != conditionTrigger) {
//debug
//if((*stopRequest != 0)){
//REPORT_ERROR(ErrorManagement::Debug, "Stop request was called.!!!");
//} else {
//REPORT_ERROR(ErrorManagement::Debug, "PLC_ON was reset.!!!");
//}
*outputSignal -= aps_swon;
mhvps_hvon_is_on = false; mhvps_hvon_state=0;
aps_hvon_is_on = false; aps_hvon_state=0;
aps_swon_is_on = false; aps_swon_state=0;
bps_hvon_is_on = false; bps_hvon_state=0;
bps_swon_is_on = false; bps_swon_state=0;
currentState = HVTerminate;
*outputAPSHVON=0;
*outputAPSSWON=0;
*outputBPSHVON=0;
*outputBPSSWON=0;
*outputMHVPSON=0;
}
uint32 updatePeriod = 100; // in microsecnds (get this from Timer)
if ((*modePulseLengthLimit == 1u) || (getCurrentTimeUs() + updatePeriod >= (apsSwonHighResolutionTime + *triggerDelay_shotlen))) {
// Now we do busy wait
while (getCurrentTimeUs() < (apsSwonHighResolutionTime + *triggerDelay_shotlen)) {
//REPORT_ERROR(ErrorManagement::Debug, "!");
}
// We stop busy waiting #executionOverhead before expected pulse off time
//debug
//if((*modePulseLengthLimit == 1u)){
// REPORT_ERROR(ErrorManagement::Debug, "Mode limit detected.!!!");
//} else {
// REPORT_ERROR(ErrorManagement::Debug, "Shot length reached to the setpoint.!!!");
//}
//debug end.
//Do action
*outputSignal -= aps_swon; //Turn off only APS_SWON first.
mhvps_hvon_is_on = false;
aps_hvon_is_on = false;
aps_swon_is_on = false; aps_swon_state=0;
bps_hvon_is_on = false;
bps_swon_is_on = false;
*outputAPSHVON=0;
*outputAPSSWON=0;
*outputBPSHVON=0;
*outputBPSSWON=0;
*outputMHVPSON=0;
//REPORT_ERROR(ErrorManagement::Debug, "0 was set to outputSignal at %d.", *currentTime);
}
*outputRFON = 1;
*outputBeamONTime = *currentTime - plcOnTime;
*outputRFONTime = *currentTime - apsSwonTime;
//State transition condition
if (!aps_swon_is_on && !bps_swon_is_on && !mhvps_hvon_is_on) {
currentState = HVTerminate;
apsSwoffTime = *currentTime;
//REPORT_ERROR(ErrorManagement::Debug, "state was changed to HVTerminate");
}
}
else if (currentState == HVTerminate) {
//In the HVTerminate state, turn APS_SWON off first, and wait 1ms. Finally turn other PS off.
//Action in this state.
*outputBeamON = 0;
*outputHVArmed = 0;
*outputHVInjection = 0;
*outputRFON = 0;
// State transition condition.
if (*currentTime - apsSwoffTime >= turn_off_delay){
*outputSignal = 0;
mhvps_hvon_state=0;
aps_hvon_state=0;
bps_hvon_state=0;
bps_swon_state=0;
}
if (*triggerSignal == false){
//Check PLC_ON is reset
currentState = WaitTrigger;
*outputSignal = 0;
//REPORT_ERROR(ErrorManagement::Debug, "PLC_ON was reset. The State was changed to WaitTrigger at %d.", *currentTime);
}
}
if(*short_pulse_mode == 1){
p3Value = 1*aps_hvon_state + 8*bps_hvon_state +16*bps_swon_state + 64*(*outputBeamON);
*outputSignalNI6259 = 1*aps_swon_state;
*outputSignalNI6528P3 = ~p3Value;
//REPORT_ERROR(ErrorManagement::Debug, "short pulse mode with p3: %d.", p3Value);
} else {
p3Value = 1*aps_hvon_state +2*aps_swon_state + 8*bps_hvon_state +16*bps_swon_state + 64*(*outputBeamON);
*outputSignalNI6528P3 = ~p3Value;
//REPORT_ERROR(ErrorManagement::Debug, "long pulse mode with p3: %d.", p3Value);
}
if (modulation) {
p4Value = 8*mhvps_hvon_state + 32;
}
else {
p4Value = 8*mhvps_hvon_state;
}
//*outputSignalNI6528P4 = ~(*ni6528p4Value | p4Value);
*outputSignalNI6528P4 = ~p4Value;
return true;
}
CLASS_REGISTER(JARTStateMachineGAM, "1.0")
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