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pigweed / third_party / github / project-chip / connectedhomeip / b2234c248931d3666bf1a81edc6a6328e6ee74a4 / . / examples / energy-management-app / energy-management-common / src / EnergyEvseDelegateImpl.cpp
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/*
*
* Copyright (c) 2023 Project CHIP Authors
* All rights reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <EnergyEvseDelegateImpl.h>
#include <app-common/zap-generated/attributes/Accessors.h>
#include <app-common/zap-generated/cluster-objects.h>
#include <app/EventLogging.h>
#include <app/SafeAttributePersistenceProvider.h>
using namespace chip;
using namespace chip::app;
using namespace chip::app::DataModel;
using namespace chip::app::Clusters;
using namespace chip::app::Clusters::EnergyEvse;
using namespace chip::app::Clusters::EnergyEvse::Attributes;
using chip::app::LogEvent;
using chip::Protocols::InteractionModel::Status;
EnergyEvseDelegate::~EnergyEvseDelegate()
{
// TODO Fix this as part of issue #30993 refactoring
if (!mVehicleID.IsNull())
{
ChipLogDetail(AppServer, "Freeing VehicleID");
delete[] mVehicleID.Value().data();
}
}
/**
* @brief Helper function to get current timestamp in Epoch format
*
* @param chipEpoch reference to hold return timestamp
*/
CHIP_ERROR GetEpochTS(uint32_t & chipEpoch);
/**
* @brief Called when EVSE cluster receives Disable command
*/
Status EnergyEvseDelegate::Disable()
{
ChipLogProgress(AppServer, "EnergyEvseDelegate::Disable()");
DataModel::Nullable<uint32_t> disableTime(0);
/* update ChargingEnabledUntil & DischargingEnabledUntil to show 0 */
SetChargingEnabledUntil(disableTime);
SetDischargingEnabledUntil(disableTime);
/* update MinimumChargeCurrent & MaximumChargeCurrent to 0 */
SetMinimumChargeCurrent(0);
SetMaximumChargeCurrent(0);
/* update MaximumDischargeCurrent to 0 */
SetMaximumDischargeCurrent(0);
return HandleStateMachineEvent(EVSEStateMachineEvent::DisabledEvent);
}
/**
* @brief Called when EVSE cluster receives EnableCharging command
*
* @param chargingEnabledUntil (can be null to indefinite charging)
* @param minimumChargeCurrent (in mA)
* @param maximumChargeCurrent (in mA)
*/
Status EnergyEvseDelegate::EnableCharging(const DataModel::Nullable<uint32_t> & chargingEnabledUntil,
const int64_t & minimumChargeCurrent, const int64_t & maximumChargeCurrent)
{
ChipLogProgress(AppServer, "EnergyEvseDelegate::EnableCharging()");
if (maximumChargeCurrent < kMinimumChargeCurrent || maximumChargeCurrent > kMaximumChargeCurrent)
{
ChipLogError(AppServer, "Maximum Current outside limits");
return Status::ConstraintError;
}
if (minimumChargeCurrent < kMinimumChargeCurrent || minimumChargeCurrent > kMaximumChargeCurrent)
{
ChipLogError(AppServer, "Maximum Current outside limits");
return Status::ConstraintError;
}
if (minimumChargeCurrent > maximumChargeCurrent)
{
ChipLogError(AppServer, "Minium Current > Maximum Current!");
return Status::ConstraintError;
}
if (chargingEnabledUntil.IsNull())
{
/* Charging enabled indefinitely */
ChipLogError(AppServer, "Charging enabled indefinitely");
SetChargingEnabledUntil(chargingEnabledUntil);
}
else
{
/* check chargingEnabledUntil is in the future */
ChipLogError(AppServer, "Charging enabled until: %lu", static_cast<long unsigned int>(chargingEnabledUntil.Value()));
SetChargingEnabledUntil(chargingEnabledUntil);
}
/* If it looks ok, store the min & max charging current */
mMaximumChargingCurrentLimitFromCommand = maximumChargeCurrent;
SetMinimumChargeCurrent(minimumChargeCurrent);
// TODO persist these to KVS
ComputeMaxChargeCurrentLimit();
return HandleStateMachineEvent(EVSEStateMachineEvent::ChargingEnabledEvent);
}
/**
* @brief Called when EVSE cluster receives EnableDischarging command
*
* @param dischargingEnabledUntil (can be null to indefinite discharging)
* @param maximumDischargeCurrent (in mA)
*/
Status EnergyEvseDelegate::EnableDischarging(const DataModel::Nullable<uint32_t> & dischargingEnabledUntil,
const int64_t & maximumDischargeCurrent)
{
ChipLogProgress(AppServer, "EnergyEvseDelegate::EnableDischarging() called.");
// TODO save the maxDischarging Current
// TODO Do something with timestamp
return HandleStateMachineEvent(EVSEStateMachineEvent::DischargingEnabledEvent);
}
/**
* @brief Routine to help schedule a timer callback to check if the EVSE should go disabled
*
* If the clock is sync'd we can work out when to call back to check when to disable the EVSE
* automatically. If the clock isn't sync'd the we just set a timer to check once every 30s.
*
* We first check the SupplyState to check if it is EnabledCharging or EnabledDischarging
* Then if the EnabledCharging/DischargingUntil is not Null, then we compute a delay to come
* back and check.
*/
Status EnergyEvseDelegate::ScheduleCheckOnEnabledTimeout()
{
uint32_t chipEpoch = 0;
DataModel::Nullable<uint32_t> enabledUntilTime;
if (mSupplyState == SupplyStateEnum::kChargingEnabled)
{
enabledUntilTime = GetChargingEnabledUntil();
}
else if (mSupplyState == SupplyStateEnum::kDischargingEnabled)
{
enabledUntilTime = GetDischargingEnabledUntil();
}
else
{
// In all other states the EVSE is disabled
return Status::Success;
}
if (enabledUntilTime.IsNull())
{
/* This is enabled indefinitely so don't schedule a callback */
return Status::Success;
}
CHIP_ERROR err = GetEpochTS(chipEpoch);
if (err == CHIP_NO_ERROR)
{
/* time is sync'd */
int32_t delta = static_cast<int32_t>(enabledUntilTime.Value() - chipEpoch);
if (delta > 0)
{
/* The timer hasn't expired yet - set a timer to check in the future */
ChipLogDetail(AppServer, "Setting EVSE Enable check timer for %ld seconds", static_cast<long int>(delta));
DeviceLayer::SystemLayer().StartTimer(System::Clock::Seconds32(delta), EvseCheckTimerExpiry, this);
}
else
{
/* we have gone past the enabledUntilTime - so we need to disable */
ChipLogDetail(AppServer, "EVSE enable time expired, disabling charging");
Disable();
}
}
else if (err == CHIP_ERROR_REAL_TIME_NOT_SYNCED)
{
/* Real time isn't sync'd -lets check again in 30 seconds - otherwise keep the charger enabled */
DeviceLayer::SystemLayer().StartTimer(System::Clock::Seconds32(kPeriodicCheckIntervalRealTimeClockNotSynced),
EvseCheckTimerExpiry, this);
}
return Status::Success;
}
void EnergyEvseDelegate::EvseCheckTimerExpiry(System::Layer * systemLayer, void * delegate)
{
EnergyEvseDelegate * dg = reinterpret_cast<EnergyEvseDelegate *>(delegate);
dg->ScheduleCheckOnEnabledTimeout();
}
/**
* @brief Called when EVSE cluster receives StartDiagnostics command
*
* NOTE: Application code needs to call HwDiagnosticsComplete
* once diagnostics have been completed.
*/
Status EnergyEvseDelegate::StartDiagnostics()
{
/* For EVSE manufacturers to customize */
ChipLogProgress(AppServer, "EnergyEvseDelegate::StartDiagnostics()");
if (mSupplyState != SupplyStateEnum::kDisabled)
{
ChipLogError(AppServer, "EVSE: cannot be put into diagnostics mode if it is not Disabled!");
return Status::Failure;
}
// Update the SupplyState - this will automatically callback the Application StateChanged callback
SetSupplyState(SupplyStateEnum::kDisabledDiagnostics);
return Status::Success;
}
/* ---------------------------------------------------------------------------
* EVSE Hardware interface below
*/
/**
* @brief Called by EVSE Hardware to register a callback handler mechanism
*
* This is normally called at start-up.
*
* @param EVSECallbackFunct - function pointer to call
* @param intptr_t - optional context to provide back to callback handler
*/
Status EnergyEvseDelegate::HwRegisterEvseCallbackHandler(EVSECallbackFunc handler, intptr_t arg)
{
if (mCallbacks.handler != nullptr)
{
ChipLogError(AppServer, "Callback handler already initialized");
return Status::Failure;
}
mCallbacks.handler = handler;
mCallbacks.arg = arg;
return Status::Success;
}
/**
* @brief Called by EVSE Hardware to notify the delegate of the maximum
* current limit supported by the hardware.
*
* This is normally called at start-up.
*
* @param currentmA - Maximum current limit supported by the hardware
*/
Status EnergyEvseDelegate::HwSetMaxHardwareCurrentLimit(int64_t currentmA)
{
if (currentmA < kMinimumChargeCurrent || currentmA > kMaximumChargeCurrent)
{
return Status::ConstraintError;
}
/* there is no attribute to store this so store in private variable */
mMaxHardwareCurrentLimit = currentmA;
return ComputeMaxChargeCurrentLimit();
}
/**
* @brief Called by EVSE Hardware to notify the delegate of maximum electrician
* set current limit.
*
* This is normally called at start-up when reading from DIP-switch
* settings.
*
* @param currentmA - Maximum current limit specified by electrician
*/
Status EnergyEvseDelegate::HwSetCircuitCapacity(int64_t currentmA)
{
if (currentmA < kMinimumChargeCurrent || currentmA > kMaximumChargeCurrent)
{
return Status::ConstraintError;
}
mCircuitCapacity = currentmA;
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, CircuitCapacity::Id);
return ComputeMaxChargeCurrentLimit();
}
/**
* @brief Called by EVSE Hardware to notify the delegate of the cable assembly
* current limit.
*
* This is normally called when the EV is plugged into the EVSE and the
* PP voltage is measured by the EVSE. A pull-up resistor in the cable
* causes a voltage drop. Different current limits can be indicated
* using different resistors, which results in different voltages
* measured by the EVSE.
*
* @param currentmA - Maximum current limit detected from Cable assembly
*/
Status EnergyEvseDelegate::HwSetCableAssemblyLimit(int64_t currentmA)
{
if (currentmA < kMinimumChargeCurrent || currentmA > kMaximumChargeCurrent)
{
return Status::ConstraintError;
}
/* there is no attribute to store this so store in private variable */
mCableAssemblyCurrentLimit = currentmA;
return ComputeMaxChargeCurrentLimit();
}
/**
* @brief Called by EVSE Hardware to indicate if EV is detected
*
* The only allowed states that the EVSE hardware can tell us about are:
* kNotPluggedIn
* kPluggedInNoDemand
* kPluggedInDemand
*
* The actual overall state is more complex and includes faults,
* enable & disable charging or discharging etc.
*
* @param StateEnum - the state of the EV being plugged in and asking for demand etc
*/
Status EnergyEvseDelegate::HwSetState(StateEnum newState)
{
switch (newState)
{
case StateEnum::kNotPluggedIn:
switch (mHwState)
{
case StateEnum::kNotPluggedIn:
// No change
break;
case StateEnum::kPluggedInNoDemand:
case StateEnum::kPluggedInDemand:
/* EVSE has been unplugged now */
mHwState = newState;
HandleStateMachineEvent(EVSEStateMachineEvent::EVNotDetectedEvent);
break;
default:
// invalid value for mHwState
ChipLogError(AppServer, "HwSetState newstate(kNotPluggedIn) - Invalid value for mHwState");
mHwState = newState; // set it to the new state anyway
break;
}
break;
case StateEnum::kPluggedInNoDemand:
switch (mHwState)
{
case StateEnum::kNotPluggedIn:
/* EV was unplugged, now is plugged in */
mHwState = newState;
HandleStateMachineEvent(EVSEStateMachineEvent::EVPluggedInEvent);
break;
case StateEnum::kPluggedInNoDemand:
// No change
break;
case StateEnum::kPluggedInDemand:
/* EV was plugged in and wanted demand, now doesn't want demand */
mHwState = newState;
HandleStateMachineEvent(EVSEStateMachineEvent::EVNoDemandEvent);
break;
default:
// invalid value for mHwState
ChipLogError(AppServer, "HwSetState newstate(kPluggedInNoDemand) - Invalid value for mHwState");
mHwState = newState; // set it to the new state anyway
break;
}
break;
case StateEnum::kPluggedInDemand:
switch (mHwState)
{
case StateEnum::kNotPluggedIn:
/* EV was unplugged, now is plugged in and wants demand */
mHwState = newState;
HandleStateMachineEvent(EVSEStateMachineEvent::EVPluggedInEvent);
HandleStateMachineEvent(EVSEStateMachineEvent::EVDemandEvent);
break;
case StateEnum::kPluggedInNoDemand:
/* EV was plugged in and didn't want demand, now does want demand */
mHwState = newState;
HandleStateMachineEvent(EVSEStateMachineEvent::EVDemandEvent);
break;
case StateEnum::kPluggedInDemand:
// No change
break;
default:
// invalid value for mHwState
ChipLogError(AppServer, "HwSetState newstate(kPluggedInDemand) - Invalid value for mHwState");
mHwState = newState; // set it to the new state anyway
break;
}
break;
default:
/* All other states should be managed by the Delegate */
ChipLogError(AppServer, "HwSetState received invalid enum from caller");
return Status::Failure;
}
return Status::Success;
}
/**
* @brief Called by EVSE Hardware to indicate a fault
*
* @param FaultStateEnum - the fault condition detected
*/
Status EnergyEvseDelegate::HwSetFault(FaultStateEnum newFaultState)
{
ChipLogProgress(AppServer, "EnergyEvseDelegate::Fault()");
if (mFaultState == newFaultState)
{
ChipLogError(AppServer, "No change in fault state, ignoring call");
return Status::Failure;
}
/** Before we do anything we log the fault
* any change in FaultState reports previous fault and new fault
* and the state prior to the fault being raised */
SendFaultEvent(newFaultState);
/* Updated FaultState before we call into the handlers */
SetFaultState(newFaultState);
if (newFaultState == FaultStateEnum::kNoError)
{
/* Fault has been cleared */
HandleStateMachineEvent(EVSEStateMachineEvent::FaultCleared);
}
else
{
/* a new Fault has been raised */
HandleStateMachineEvent(EVSEStateMachineEvent::FaultRaised);
}
return Status::Success;
}
/**
* @brief Called by EVSE Hardware to Send a RFID event
*
* @param ByteSpan RFID tag value (max 10 octets)
*/
Status EnergyEvseDelegate::HwSetRFID(ByteSpan uid)
{
Events::Rfid::Type event{ .uid = uid };
EventNumber eventNumber;
CHIP_ERROR error = LogEvent(event, mEndpointId, eventNumber);
if (CHIP_NO_ERROR != error)
{
ChipLogError(Zcl, "[Notify] Unable to send notify event: %s [endpointId=%d]", error.AsString(), mEndpointId);
return Status::Failure;
}
return Status::Success;
}
/**
* @brief Called by EVSE Hardware to share the VehicleID
*
* This routine will make a copy of the string so the callee doesn't
* have to hold onto it forever.
*
* @param CharSpan containing up to 32 chars.
*/
Status EnergyEvseDelegate::HwSetVehicleID(const CharSpan & newValue)
{
// TODO this code to be refactored - See Issue #30993
if (!mVehicleID.IsNull() && newValue.data_equal(mVehicleID.Value()))
{
return Status::Success;
}
/* create a copy of the string so the callee doesn't have to keep it */
char * destinationBuffer = new char[kMaxVehicleIDBufSize];
MutableCharSpan destinationString(destinationBuffer, kMaxVehicleIDBufSize);
CHIP_ERROR err = CopyCharSpanToMutableCharSpan(newValue, destinationString);
if (err != CHIP_NO_ERROR)
{
ChipLogError(AppServer, "HwSetVehicleID - could not copy vehicleID");
delete[] destinationBuffer;
return Status::Failure;
}
if (!mVehicleID.IsNull())
{
delete[] mVehicleID.Value().data();
}
mVehicleID = MakeNullable(static_cast<CharSpan>(destinationString));
ChipLogDetail(AppServer, "VehicleID updated %.*s", static_cast<int>(mVehicleID.Value().size()), mVehicleID.Value().data());
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, VehicleID::Id);
return Status::Success;
}
/**
* @brief Called by EVSE Hardware to indicate that it has finished its diagnostics test
*/
Status EnergyEvseDelegate::HwDiagnosticsComplete()
{
if (mSupplyState != SupplyStateEnum::kDisabledDiagnostics)
{
ChipLogError(AppServer, "Incorrect state to be completing diagnostics");
return Status::Failure;
}
/* Restore the SupplyState to Disabled (per spec) - client will need to
* re-enable charging or discharging to get out of this state */
SetSupplyState(SupplyStateEnum::kDisabled);
return Status::Success;
}
/* ---------------------------------------------------------------------------
* Functions below are private helper functions internal to the delegate
*/
/**
* @brief Main EVSE state machine
*
* This routine handles state transition events to determine behaviour
*
*
*/
Status EnergyEvseDelegate::HandleStateMachineEvent(EVSEStateMachineEvent event)
{
switch (event)
{
case EVSEStateMachineEvent::EVPluggedInEvent:
ChipLogDetail(AppServer, "EVSE: EV PluggedIn event");
return HandleEVPluggedInEvent();
break;
case EVSEStateMachineEvent::EVNotDetectedEvent:
ChipLogDetail(AppServer, "EVSE: EV NotDetected event");
return HandleEVNotDetectedEvent();
break;
case EVSEStateMachineEvent::EVNoDemandEvent:
ChipLogDetail(AppServer, "EVSE: EV NoDemand event");
return HandleEVNoDemandEvent();
break;
case EVSEStateMachineEvent::EVDemandEvent:
ChipLogDetail(AppServer, "EVSE: EV Demand event");
return HandleEVDemandEvent();
break;
case EVSEStateMachineEvent::ChargingEnabledEvent:
ChipLogDetail(AppServer, "EVSE: ChargingEnabled event");
return HandleChargingEnabledEvent();
break;
case EVSEStateMachineEvent::DischargingEnabledEvent:
ChipLogDetail(AppServer, "EVSE: DischargingEnabled event");
return HandleDischargingEnabledEvent();
break;
case EVSEStateMachineEvent::DisabledEvent:
ChipLogDetail(AppServer, "EVSE: Disabled event");
return HandleDisabledEvent();
break;
case EVSEStateMachineEvent::FaultRaised:
ChipLogDetail(AppServer, "EVSE: FaultRaised event");
return HandleFaultRaised();
break;
case EVSEStateMachineEvent::FaultCleared:
ChipLogDetail(AppServer, "EVSE: FaultCleared event");
return HandleFaultCleared();
break;
default:
return Status::Failure;
}
return Status::Success;
}
Status EnergyEvseDelegate::HandleEVPluggedInEvent()
{
/* check if we are already plugged in or not */
if (mState == StateEnum::kNotPluggedIn)
{
/* EV was not plugged in - start a new session */
// TODO get energy meter readings
mSession.StartSession(0, 0);
SendEVConnectedEvent();
/* Set the state to either PluggedInNoDemand or PluggedInDemand as indicated by mHwState */
SetState(mHwState);
}
// else we are already plugged in - ignore
return Status::Success;
}
Status EnergyEvseDelegate::HandleEVNotDetectedEvent()
{
if (mState == StateEnum::kPluggedInCharging || mState == StateEnum::kPluggedInDischarging)
{
/*
* EV was transferring current - unusual to get to this case without
* first having the state set to kPluggedInNoDemand or kPluggedInDemand
*/
SendEnergyTransferStoppedEvent(EnergyTransferStoppedReasonEnum::kOther);
}
SendEVNotDetectedEvent();
SetState(StateEnum::kNotPluggedIn);
return Status::Success;
}
Status EnergyEvseDelegate::HandleEVNoDemandEvent()
{
if (mState == StateEnum::kPluggedInCharging || mState == StateEnum::kPluggedInDischarging)
{
/*
* EV was transferring current - EV decided to stop
*/
mSession.RecalculateSessionDuration();
SendEnergyTransferStoppedEvent(EnergyTransferStoppedReasonEnum::kEVStopped);
}
/* We must still be plugged in to get here - so no need to check if we are plugged in! */
SetState(StateEnum::kPluggedInNoDemand);
return Status::Success;
}
Status EnergyEvseDelegate::HandleEVDemandEvent()
{
/* Check to see if the supply is enabled for charging / discharging*/
switch (mSupplyState)
{
case SupplyStateEnum::kChargingEnabled:
ComputeMaxChargeCurrentLimit();
SetState(StateEnum::kPluggedInCharging);
SendEnergyTransferStartedEvent();
break;
case SupplyStateEnum::kDischargingEnabled:
// TODO ComputeMaxDischargeCurrentLimit() - Needs to be implemented
SetState(StateEnum::kPluggedInDischarging);
SendEnergyTransferStartedEvent();
break;
case SupplyStateEnum::kDisabled:
case SupplyStateEnum::kDisabledError:
case SupplyStateEnum::kDisabledDiagnostics:
/* We must be plugged in, and the event is asking for demand
* but we can't charge or discharge now - leave it as kPluggedInDemand */
SetState(StateEnum::kPluggedInDemand);
break;
default:
break;
}
return Status::Success;
}
Status EnergyEvseDelegate::CheckFaultOrDiagnostic()
{
if (mFaultState != FaultStateEnum::kNoError)
{
ChipLogError(AppServer, "EVSE: Trying to handle command when fault is present");
return Status::Failure;
}
if (mSupplyState == SupplyStateEnum::kDisabledDiagnostics)
{
ChipLogError(AppServer, "EVSE: Trying to handle command when in diagnostics mode");
return Status::Failure;
}
return Status::Success;
}
Status EnergyEvseDelegate::HandleChargingEnabledEvent()
{
/* Check there is no Fault or Diagnostics condition */
Status status = CheckFaultOrDiagnostic();
if (status != Status::Success)
{
return status;
}
/* update SupplyState to say that charging is now enabled */
SetSupplyState(SupplyStateEnum::kChargingEnabled);
switch (mState)
{
case StateEnum::kNotPluggedIn:
case StateEnum::kPluggedInNoDemand:
break;
case StateEnum::kPluggedInDemand:
ComputeMaxChargeCurrentLimit();
SetState(StateEnum::kPluggedInCharging);
SendEnergyTransferStartedEvent();
break;
case StateEnum::kPluggedInCharging:
break;
case StateEnum::kPluggedInDischarging:
/* Switched from discharging to charging */
SendEnergyTransferStoppedEvent(EnergyTransferStoppedReasonEnum::kEVSEStopped);
ComputeMaxChargeCurrentLimit();
SetState(StateEnum::kPluggedInCharging);
SendEnergyTransferStartedEvent();
break;
default:
break;
}
ScheduleCheckOnEnabledTimeout();
return Status::Success;
}
Status EnergyEvseDelegate::HandleDischargingEnabledEvent()
{
/* Check there is no Fault or Diagnostics condition */
Status status = CheckFaultOrDiagnostic();
if (status != Status::Success)
{
return status;
}
/* update SupplyState to say that charging is now enabled */
SetSupplyState(SupplyStateEnum::kDischargingEnabled);
switch (mState)
{
case StateEnum::kNotPluggedIn:
case StateEnum::kPluggedInNoDemand:
break;
case StateEnum::kPluggedInDemand:
// TODO call ComputeMaxDischargeCurrentLimit()
SetState(StateEnum::kPluggedInDischarging);
SendEnergyTransferStartedEvent();
break;
case StateEnum::kPluggedInCharging:
/* Switched from charging to discharging */
SendEnergyTransferStoppedEvent(EnergyTransferStoppedReasonEnum::kEVSEStopped);
// TODO call ComputeMaxDischargeCurrentLimit()
SetState(StateEnum::kPluggedInDischarging);
SendEnergyTransferStartedEvent();
break;
case StateEnum::kPluggedInDischarging:
default:
break;
}
ScheduleCheckOnEnabledTimeout();
return Status::Success;
}
Status EnergyEvseDelegate::HandleDisabledEvent()
{
/* Check there is no Fault or Diagnostics condition */
Status status = CheckFaultOrDiagnostic();
if (status != Status::Success)
{
return status;
}
/* update SupplyState to say that charging is now enabled */
SetSupplyState(SupplyStateEnum::kDisabled);
switch (mState)
{
case StateEnum::kNotPluggedIn:
case StateEnum::kPluggedInNoDemand:
case StateEnum::kPluggedInDemand:
break;
case StateEnum::kPluggedInCharging:
case StateEnum::kPluggedInDischarging:
SendEnergyTransferStoppedEvent(EnergyTransferStoppedReasonEnum::kEVSEStopped);
SetState(mHwState);
break;
default:
break;
}
return Status::Success;
}
/**
* @brief This handles the new fault
*
* Note that if multiple faults happen and this is called repeatedly
* We only save the previous State and SupplyState if its the first raising
* of the fault, so we can restore the state back once all faults have cleared
)*/
Status EnergyEvseDelegate::HandleFaultRaised()
{
/* Save the current State and SupplyState so we can restore them if the fault clears */
if (mStateBeforeFault == StateEnum::kUnknownEnumValue)
{
/* No existing fault - save this value to restore it later if it clears */
mStateBeforeFault = mState;
}
if (mSupplyStateBeforeFault == SupplyStateEnum::kUnknownEnumValue)
{
/* No existing fault */
mSupplyStateBeforeFault = mSupplyState;
}
/* Update State & SupplyState */
SetState(StateEnum::kFault);
SetSupplyState(SupplyStateEnum::kDisabledError);
return Status::Success;
}
Status EnergyEvseDelegate::HandleFaultCleared()
{
/* Check that something strange hasn't happened */
if ((mStateBeforeFault == StateEnum::kUnknownEnumValue) || (mSupplyStateBeforeFault == SupplyStateEnum::kUnknownEnumValue))
{
ChipLogError(AppServer, "EVSE: Something wrong trying to clear fault");
return Status::Failure;
}
/* Restore the State and SupplyState back to old values once all the faults have cleared
* Changing the State should notify the application, so it can continue charging etc
*/
SetState(mStateBeforeFault);
SetSupplyState(mSupplyStateBeforeFault);
/* put back the sentinel to catch new faults if more are raised */
mStateBeforeFault = StateEnum::kUnknownEnumValue;
mSupplyStateBeforeFault = SupplyStateEnum::kUnknownEnumValue;
return Status::Success;
}
/**
* @brief Called to compute the safe charging current limit
*
* mActualChargingCurrentLimit is the minimum of:
* - MaxHardwareCurrentLimit (of the hardware)
* - CircuitCapacity (set by the electrician - less than the hardware)
* - CableAssemblyLimit (detected when the cable is inserted)
* - MaximumChargeCurrent (from charging command)
* - UserMaximumChargeCurrent (could dynamically change)
*
*/
Status EnergyEvseDelegate::ComputeMaxChargeCurrentLimit()
{
int64_t oldValue;
oldValue = mActualChargingCurrentLimit;
mActualChargingCurrentLimit = mMaxHardwareCurrentLimit;
mActualChargingCurrentLimit = min(mActualChargingCurrentLimit, mCircuitCapacity);
mActualChargingCurrentLimit = min(mActualChargingCurrentLimit, mCableAssemblyCurrentLimit);
mActualChargingCurrentLimit = min(mActualChargingCurrentLimit, mMaximumChargingCurrentLimitFromCommand);
mActualChargingCurrentLimit = min(mActualChargingCurrentLimit, mUserMaximumChargeCurrent);
/* Set the actual max charging current attribute */
mMaximumChargeCurrent = mActualChargingCurrentLimit;
if (oldValue != mMaximumChargeCurrent)
{
ChipLogDetail(AppServer, "MaximumChargeCurrent updated to %ld", static_cast<long>(mMaximumChargeCurrent));
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, MaximumChargeCurrent::Id);
/* Call the EV Charger hardware current limit callback */
NotifyApplicationCurrentLimitChange(mMaximumChargeCurrent);
}
return Status::Success;
}
Status EnergyEvseDelegate::NotifyApplicationCurrentLimitChange(int64_t maximumChargeCurrent)
{
EVSECbInfo cbInfo;
cbInfo.type = EVSECallbackType::ChargeCurrentChanged;
cbInfo.ChargingCurrent.maximumChargeCurrent = maximumChargeCurrent;
if (mCallbacks.handler != nullptr)
{
mCallbacks.handler(&cbInfo, mCallbacks.arg);
}
return Status::Success;
}
Status EnergyEvseDelegate::NotifyApplicationStateChange()
{
EVSECbInfo cbInfo;
cbInfo.type = EVSECallbackType::StateChanged;
cbInfo.StateChange.state = mState;
cbInfo.StateChange.supplyState = mSupplyState;
if (mCallbacks.handler != nullptr)
{
mCallbacks.handler(&cbInfo, mCallbacks.arg);
}
return Status::Success;
}
Status EnergyEvseDelegate::GetEVSEEnergyMeterValue(ChargingDischargingType meterType, int64_t & aMeterValue)
{
EVSECbInfo cbInfo;
cbInfo.type = EVSECallbackType::EnergyMeterReadingRequested;
cbInfo.EnergyMeterReadingRequest.meterType = meterType;
cbInfo.EnergyMeterReadingRequest.energyMeterValuePtr = &aMeterValue;
if (mCallbacks.handler != nullptr)
{
mCallbacks.handler(&cbInfo, mCallbacks.arg);
}
return Status::Success;
}
Status EnergyEvseDelegate::SendEVConnectedEvent()
{
Events::EVConnected::Type event;
EventNumber eventNumber;
if (mSession.mSessionID.IsNull())
{
ChipLogError(AppServer, "SessionID is Null");
return Status::Failure;
}
event.sessionID = mSession.mSessionID.Value();
CHIP_ERROR err = LogEvent(event, mEndpointId, eventNumber);
if (CHIP_NO_ERROR != err)
{
ChipLogError(AppServer, "Unable to send notify event: %" CHIP_ERROR_FORMAT, err.Format());
return Status::Failure;
}
return Status::Success;
}
Status EnergyEvseDelegate::SendEVNotDetectedEvent()
{
Events::EVNotDetected::Type event;
EventNumber eventNumber;
if (mSession.mSessionID.IsNull())
{
ChipLogError(AppServer, "SessionID is Null");
return Status::Failure;
}
event.sessionID = mSession.mSessionID.Value();
event.state = mState;
event.sessionDuration = mSession.mSessionDuration.Value();
event.sessionEnergyCharged = mSession.mSessionEnergyCharged.Value();
event.sessionEnergyDischarged = MakeOptional(mSession.mSessionEnergyDischarged.Value());
CHIP_ERROR err = LogEvent(event, mEndpointId, eventNumber);
if (CHIP_NO_ERROR != err)
{
ChipLogError(AppServer, "Unable to send notify event: %" CHIP_ERROR_FORMAT, err.Format());
return Status::Failure;
}
return Status::Success;
}
Status EnergyEvseDelegate::SendEnergyTransferStartedEvent()
{
Events::EnergyTransferStarted::Type event;
EventNumber eventNumber;
if (mSession.mSessionID.IsNull())
{
ChipLogError(AppServer, "SessionID is Null");
return Status::Failure;
}
event.sessionID = mSession.mSessionID.Value();
event.state = mState;
/**
* A positive value indicates the EV has been enabled for charging and the value is
* taken directly from the MaximumChargeCurrent attribute.
* A negative value indicates that the EV has been enabled for discharging and the value can be taken
* from the MaximumDischargeCurrent attribute with its sign inverted.
*/
if (mState == StateEnum::kPluggedInCharging)
{
/* Sample the energy meter for charging */
GetEVSEEnergyMeterValue(ChargingDischargingType::kCharging, mMeterValueAtEnergyTransferStart);
event.maximumCurrent = mMaximumChargeCurrent;
}
else if (mState == StateEnum::kPluggedInDischarging)
{
/* Sample the energy meter for discharging */
GetEVSEEnergyMeterValue(ChargingDischargingType::kDischarging, mMeterValueAtEnergyTransferStart);
/* discharging should have a negative current */
event.maximumCurrent = -mMaximumDischargeCurrent;
}
CHIP_ERROR err = LogEvent(event, mEndpointId, eventNumber);
if (CHIP_NO_ERROR != err)
{
ChipLogError(AppServer, "Unable to send notify event: %" CHIP_ERROR_FORMAT, err.Format());
return Status::Failure;
}
return Status::Success;
}
Status EnergyEvseDelegate::SendEnergyTransferStoppedEvent(EnergyTransferStoppedReasonEnum reason)
{
Events::EnergyTransferStopped::Type event;
EventNumber eventNumber;
if (mSession.mSessionID.IsNull())
{
ChipLogError(AppServer, "SessionID is Null");
return Status::Failure;
}
event.sessionID = mSession.mSessionID.Value();
event.state = mState;
event.reason = reason;
int64_t meterValueNow = 0;
if (mState == StateEnum::kPluggedInCharging)
{
GetEVSEEnergyMeterValue(ChargingDischargingType::kCharging, meterValueNow);
event.energyTransferred = meterValueNow - mMeterValueAtEnergyTransferStart;
}
else if (mState == StateEnum::kPluggedInDischarging)
{
GetEVSEEnergyMeterValue(ChargingDischargingType::kDischarging, meterValueNow);
/* discharging should have a negative value */
event.energyTransferred = mMeterValueAtEnergyTransferStart - meterValueNow;
}
CHIP_ERROR err = LogEvent(event, mEndpointId, eventNumber);
if (CHIP_NO_ERROR != err)
{
ChipLogError(AppServer, "Unable to send notify event: %" CHIP_ERROR_FORMAT, err.Format());
return Status::Failure;
}
return Status::Success;
}
Status EnergyEvseDelegate::SendFaultEvent(FaultStateEnum newFaultState)
{
Events::Fault::Type event;
EventNumber eventNumber;
event.sessionID = mSession.mSessionID; // Note here the event sessionID can be Null!
event.state = mState; // This is the state prior to the fault being raised
event.faultStatePreviousState = mFaultState;
event.faultStateCurrentState = newFaultState;
CHIP_ERROR err = LogEvent(event, mEndpointId, eventNumber);
if (CHIP_NO_ERROR != err)
{
ChipLogError(AppServer, "Unable to send notify event: %" CHIP_ERROR_FORMAT, err.Format());
return Status::Failure;
}
return Status::Success;
}
/**
* Attribute methods
*/
/* State */
StateEnum EnergyEvseDelegate::GetState()
{
return mState;
}
CHIP_ERROR EnergyEvseDelegate::SetState(StateEnum newValue)
{
StateEnum oldValue = mState;
if (newValue >= StateEnum::kUnknownEnumValue)
{
return CHIP_IM_GLOBAL_STATUS(ConstraintError);
}
mState = newValue;
if (oldValue != mState)
{
ChipLogDetail(AppServer, "State updated to %d", static_cast<int>(mState));
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, State::Id);
NotifyApplicationStateChange();
}
return CHIP_NO_ERROR;
}
/* SupplyState */
SupplyStateEnum EnergyEvseDelegate::GetSupplyState()
{
return mSupplyState;
}
CHIP_ERROR EnergyEvseDelegate::SetSupplyState(SupplyStateEnum newValue)
{
SupplyStateEnum oldValue = mSupplyState;
if (newValue >= SupplyStateEnum::kUnknownEnumValue)
{
return CHIP_IM_GLOBAL_STATUS(ConstraintError);
}
mSupplyState = newValue;
if (oldValue != mSupplyState)
{
ChipLogDetail(AppServer, "SupplyState updated to %d", static_cast<int>(mSupplyState));
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, SupplyState::Id);
NotifyApplicationStateChange();
}
return CHIP_NO_ERROR;
}
/* FaultState */
FaultStateEnum EnergyEvseDelegate::GetFaultState()
{
return mFaultState;
}
CHIP_ERROR EnergyEvseDelegate::SetFaultState(FaultStateEnum newValue)
{
FaultStateEnum oldValue = mFaultState;
if (newValue >= FaultStateEnum::kUnknownEnumValue)
{
return CHIP_IM_GLOBAL_STATUS(ConstraintError);
}
mFaultState = newValue;
if (oldValue != mFaultState)
{
ChipLogDetail(AppServer, "FaultState updated to %d", static_cast<int>(mFaultState));
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, FaultState::Id);
}
return CHIP_NO_ERROR;
}
/* ChargingEnabledUntil */
DataModel::Nullable<uint32_t> EnergyEvseDelegate::GetChargingEnabledUntil()
{
return mChargingEnabledUntil;
}
CHIP_ERROR EnergyEvseDelegate::SetChargingEnabledUntil(DataModel::Nullable<uint32_t> newValue)
{
DataModel::Nullable<uint32_t> oldValue = mChargingEnabledUntil;
mChargingEnabledUntil = newValue;
if (oldValue != newValue)
{
if (newValue.IsNull())
{
ChipLogDetail(AppServer, "ChargingEnabledUntil updated to Null");
}
else
{
ChipLogDetail(AppServer, "ChargingEnabledUntil updated to %lu",
static_cast<unsigned long int>(mChargingEnabledUntil.Value()));
}
// Write new value to persistent storage.
ConcreteAttributePath path = ConcreteAttributePath(mEndpointId, EnergyEvse::Id, ChargingEnabledUntil::Id);
GetSafeAttributePersistenceProvider()->WriteScalarValue(path, mChargingEnabledUntil);
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, ChargingEnabledUntil::Id);
}
return CHIP_NO_ERROR;
}
/* DischargingEnabledUntil */
DataModel::Nullable<uint32_t> EnergyEvseDelegate::GetDischargingEnabledUntil()
{
return mDischargingEnabledUntil;
}
CHIP_ERROR EnergyEvseDelegate::SetDischargingEnabledUntil(DataModel::Nullable<uint32_t> newValue)
{
DataModel::Nullable<uint32_t> oldValue = mDischargingEnabledUntil;
mDischargingEnabledUntil = newValue;
if (oldValue != newValue)
{
if (newValue.IsNull())
{
ChipLogDetail(AppServer, "DischargingEnabledUntil updated to Null");
}
else
{
ChipLogDetail(AppServer, "DischargingEnabledUntil updated to %lu",
static_cast<unsigned long int>(mDischargingEnabledUntil.Value()));
}
// Write new value to persistent storage.
ConcreteAttributePath path = ConcreteAttributePath(mEndpointId, EnergyEvse::Id, DischargingEnabledUntil::Id);
GetSafeAttributePersistenceProvider()->WriteScalarValue(path, mDischargingEnabledUntil);
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, DischargingEnabledUntil::Id);
}
return CHIP_NO_ERROR;
}
/* CircuitCapacity */
int64_t EnergyEvseDelegate::GetCircuitCapacity()
{
return mCircuitCapacity;
}
CHIP_ERROR EnergyEvseDelegate::SetCircuitCapacity(int64_t newValue)
{
int64_t oldValue = mCircuitCapacity;
if (newValue >= kMaximumChargeCurrent)
{
return CHIP_IM_GLOBAL_STATUS(ConstraintError);
}
mCircuitCapacity = newValue;
if (oldValue != mCircuitCapacity)
{
ChipLogDetail(AppServer, "CircuitCapacity updated to %ld", static_cast<long>(mCircuitCapacity));
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, CircuitCapacity::Id);
}
return CHIP_NO_ERROR;
}
/* MinimumChargeCurrent */
int64_t EnergyEvseDelegate::GetMinimumChargeCurrent()
{
return mMinimumChargeCurrent;
}
CHIP_ERROR EnergyEvseDelegate::SetMinimumChargeCurrent(int64_t newValue)
{
int64_t oldValue = mMinimumChargeCurrent;
if (newValue >= kMaximumChargeCurrent)
{
return CHIP_IM_GLOBAL_STATUS(ConstraintError);
}
mMinimumChargeCurrent = newValue;
if (oldValue != mMinimumChargeCurrent)
{
ChipLogDetail(AppServer, "MinimumChargeCurrent updated to %ld", static_cast<long>(mMinimumChargeCurrent));
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, MinimumChargeCurrent::Id);
}
return CHIP_NO_ERROR;
}
/* MaximumChargeCurrent */
int64_t EnergyEvseDelegate::GetMaximumChargeCurrent()
{
return mMaximumChargeCurrent;
}
CHIP_ERROR EnergyEvseDelegate::SetMaximumChargeCurrent(int64_t newValue)
{
int64_t oldValue = mMaximumChargeCurrent;
if (newValue >= kMaximumChargeCurrent)
{
return CHIP_IM_GLOBAL_STATUS(ConstraintError);
}
mMaximumChargeCurrent = newValue;
if (oldValue != mMaximumChargeCurrent)
{
ChipLogDetail(AppServer, "MaximumChargeCurrent updated to %ld", static_cast<long>(mMaximumChargeCurrent));
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, MaximumChargeCurrent::Id);
}
return CHIP_NO_ERROR;
}
/* MaximumDischargeCurrent */
int64_t EnergyEvseDelegate::GetMaximumDischargeCurrent()
{
return mMaximumDischargeCurrent;
}
CHIP_ERROR EnergyEvseDelegate::SetMaximumDischargeCurrent(int64_t newValue)
{
int64_t oldValue = mMaximumDischargeCurrent;
if (newValue >= kMaximumChargeCurrent)
{
return CHIP_IM_GLOBAL_STATUS(ConstraintError);
}
mMaximumDischargeCurrent = newValue;
if (oldValue != mMaximumDischargeCurrent)
{
ChipLogDetail(AppServer, "MaximumDischargeCurrent updated to %ld", static_cast<long>(mMaximumDischargeCurrent));
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, MaximumDischargeCurrent::Id);
}
return CHIP_NO_ERROR;
}
/* UserMaximumChargeCurrent */
int64_t EnergyEvseDelegate::GetUserMaximumChargeCurrent()
{
return mUserMaximumChargeCurrent;
}
CHIP_ERROR EnergyEvseDelegate::SetUserMaximumChargeCurrent(int64_t newValue)
{
if ((newValue < 0) || (newValue > kMaximumChargeCurrent))
{
return CHIP_IM_GLOBAL_STATUS(ConstraintError);
}
int64_t oldValue = mUserMaximumChargeCurrent;
mUserMaximumChargeCurrent = newValue;
if (oldValue != newValue)
{
ChipLogDetail(AppServer, "UserMaximumChargeCurrent updated to %ld", static_cast<long>(mUserMaximumChargeCurrent));
ComputeMaxChargeCurrentLimit();
// Write new value to persistent storage.
ConcreteAttributePath path = ConcreteAttributePath(mEndpointId, EnergyEvse::Id, UserMaximumChargeCurrent::Id);
GetSafeAttributePersistenceProvider()->WriteScalarValue(path, mUserMaximumChargeCurrent);
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, UserMaximumChargeCurrent::Id);
}
return CHIP_NO_ERROR;
}
/* RandomizationDelayWindow */
uint32_t EnergyEvseDelegate::GetRandomizationDelayWindow()
{
return mRandomizationDelayWindow;
}
CHIP_ERROR EnergyEvseDelegate::SetRandomizationDelayWindow(uint32_t newValue)
{
uint32_t oldValue = mRandomizationDelayWindow;
if (newValue > kMaxRandomizationDelayWindow)
{
return CHIP_IM_GLOBAL_STATUS(ConstraintError);
}
mRandomizationDelayWindow = newValue;
if (oldValue != newValue)
{
ChipLogDetail(AppServer, "RandomizationDelayWindow updated to %lu",
static_cast<unsigned long int>(mRandomizationDelayWindow));
// Write new value to persistent storage.
ConcreteAttributePath path = ConcreteAttributePath(mEndpointId, EnergyEvse::Id, RandomizationDelayWindow::Id);
GetSafeAttributePersistenceProvider()->WriteScalarValue(path, mRandomizationDelayWindow);
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, RandomizationDelayWindow::Id);
}
return CHIP_NO_ERROR;
}
/* PREF attributes */
DataModel::Nullable<uint32_t> EnergyEvseDelegate::GetNextChargeStartTime()
{
return mNextChargeStartTime;
}
DataModel::Nullable<uint32_t> EnergyEvseDelegate::GetNextChargeTargetTime()
{
return mNextChargeTargetTime;
}
DataModel::Nullable<int64_t> EnergyEvseDelegate::GetNextChargeRequiredEnergy()
{
return mNextChargeRequiredEnergy;
}
DataModel::Nullable<Percent> EnergyEvseDelegate::GetNextChargeTargetSoC()
{
return mNextChargeTargetSoC;
}
/* ApproximateEVEfficiency */
DataModel::Nullable<uint16_t> EnergyEvseDelegate::GetApproximateEVEfficiency()
{
return mApproximateEVEfficiency;
}
CHIP_ERROR EnergyEvseDelegate::SetApproximateEVEfficiency(DataModel::Nullable<uint16_t> newValue)
{
DataModel::Nullable<uint16_t> oldValue = mApproximateEVEfficiency;
mApproximateEVEfficiency = newValue;
if ((oldValue != newValue))
{
if (newValue.IsNull())
{
ChipLogDetail(AppServer, "ApproximateEVEfficiency updated to Null");
}
else
{
ChipLogDetail(AppServer, "ApproximateEVEfficiency updated to %d", mApproximateEVEfficiency.Value());
}
// Write new value to persistent storage.
ConcreteAttributePath path = ConcreteAttributePath(mEndpointId, EnergyEvse::Id, ApproximateEVEfficiency::Id);
GetSafeAttributePersistenceProvider()->WriteScalarValue(path, mApproximateEVEfficiency);
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, ApproximateEVEfficiency::Id);
}
return CHIP_NO_ERROR;
}
/* SOC attributes */
DataModel::Nullable<Percent> EnergyEvseDelegate::GetStateOfCharge()
{
return mStateOfCharge;
}
DataModel::Nullable<int64_t> EnergyEvseDelegate::GetBatteryCapacity()
{
return mBatteryCapacity;
}
/* PNC attributes*/
DataModel::Nullable<CharSpan> EnergyEvseDelegate::GetVehicleID()
{
return mVehicleID;
}
/* Session SESS attributes */
DataModel::Nullable<uint32_t> EnergyEvseDelegate::GetSessionID()
{
return mSession.mSessionID;
}
DataModel::Nullable<uint32_t> EnergyEvseDelegate::GetSessionDuration()
{
mSession.RecalculateSessionDuration();
return mSession.mSessionDuration;
}
DataModel::Nullable<int64_t> EnergyEvseDelegate::GetSessionEnergyCharged()
{
return mSession.mSessionEnergyCharged;
}
DataModel::Nullable<int64_t> EnergyEvseDelegate::GetSessionEnergyDischarged()
{
return mSession.mSessionEnergyDischarged;
}
/**
* @brief Helper function to get current timestamp in Epoch format
*
* @param chipEpoch reference to hold return timestamp
*/
CHIP_ERROR GetEpochTS(uint32_t & chipEpoch)
{
chipEpoch = 0;
System::Clock::Milliseconds64 cTMs;
CHIP_ERROR err = System::SystemClock().GetClock_RealTimeMS(cTMs);
/* If the GetClock_RealTimeMS returns CHIP_ERROR_UNSUPPORTED_CHIP_FEATURE, then
* This platform cannot ever report real time !
* This should not be certifiable since getting time is a Mandatory
* feature of EVSE Cluster
*/
if (err == CHIP_ERROR_UNSUPPORTED_CHIP_FEATURE)
{
ChipLogError(Zcl, "Platform does not support GetClock_RealTimeMS. Check EVSE certification requirements!");
return err;
}
if (err != CHIP_NO_ERROR)
{
ChipLogError(Zcl, "EVSE: Unable to get current time - err:%" CHIP_ERROR_FORMAT, err.Format());
return err;
}
auto unixEpoch = std::chrono::duration_cast<System::Clock::Seconds32>(cTMs).count();
if (!UnixEpochToChipEpochTime(unixEpoch, chipEpoch))
{
ChipLogError(Zcl, "EVSE: unable to convert Unix Epoch time to Matter Epoch Time");
return err;
}
return CHIP_NO_ERROR;
}
/**
* @brief This function samples the start-time, and energy meter to hold the session info
*
* @param chargingMeterValue - The current value of the energy meter (charging) in mWh
* @param dischargingMeterValue - The current value of the energy meter (discharging) in mWh
*/
void EvseSession::StartSession(int64_t chargingMeterValue, int64_t dischargingMeterValue)
{
/* Get Timestamp */
uint32_t chipEpoch = 0;
CHIP_ERROR err = GetEpochTS(chipEpoch);
if (err != CHIP_NO_ERROR)
{
/* Note that the error will be also be logged inside GetErrorTS() -
* adding context here to help debugging */
ChipLogError(AppServer, "EVSE: Unable to get current time when starting session - err:%" CHIP_ERROR_FORMAT, err.Format());
return;
}
mStartTime = chipEpoch;
mSessionEnergyChargedAtStart = chargingMeterValue;
mSessionEnergyDischargedAtStart = dischargingMeterValue;
if (mSessionID.IsNull())
{
mSessionID = MakeNullable(static_cast<uint32_t>(0));
}
else
{
uint32_t sessionID = mSessionID.Value() + 1;
mSessionID = MakeNullable(sessionID);
}
/* Reset other session values */
mSessionDuration = MakeNullable(static_cast<uint32_t>(0));
mSessionEnergyCharged = MakeNullable(static_cast<int64_t>(0));
mSessionEnergyDischarged = MakeNullable(static_cast<int64_t>(0));
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, SessionID::Id);
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, SessionDuration::Id);
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, SessionEnergyCharged::Id);
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, SessionEnergyDischarged::Id);
// Write values to persistent storage.
ConcreteAttributePath path = ConcreteAttributePath(mEndpointId, EnergyEvse::Id, SessionID::Id);
GetSafeAttributePersistenceProvider()->WriteScalarValue(path, mSessionID);
// TODO persist mStartTime
// TODO persist mSessionEnergyChargedAtStart
// TODO persist mSessionEnergyDischargedAtStart
}
/**
* @brief This function updates the session attrs to allow read attributes to return latest values
*/
void EvseSession::RecalculateSessionDuration()
{
/* Get Timestamp */
uint32_t chipEpoch = 0;
CHIP_ERROR err = GetEpochTS(chipEpoch);
if (err != CHIP_NO_ERROR)
{
/* Note that the error will be also be logged inside GetErrorTS() -
* adding context here to help debugging */
ChipLogError(AppServer, "EVSE: Unable to get current time when updating session duration - err:%" CHIP_ERROR_FORMAT,
err.Format());
return;
}
uint32_t duration = chipEpoch - mStartTime;
mSessionDuration = MakeNullable(duration);
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, SessionDuration::Id);
}
/**
* @brief This function updates the EnergyCharged meter value
*
* @param chargingMeterValue - The value of the energy meter (charging) in mWh
*/
void EvseSession::UpdateEnergyCharged(int64_t chargingMeterValue)
{
mSessionEnergyCharged = MakeNullable(chargingMeterValue - mSessionEnergyChargedAtStart);
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, SessionEnergyCharged::Id);
}
/**
* @brief This function updates the EnergyDischarged meter value
*
* @param dischargingMeterValue - The value of the energy meter (discharging) in mWh
*/
void EvseSession::UpdateEnergyDischarged(int64_t dischargingMeterValue)
{
mSessionEnergyDischarged = MakeNullable(dischargingMeterValue - mSessionEnergyDischargedAtStart);
MatterReportingAttributeChangeCallback(mEndpointId, EnergyEvse::Id, SessionEnergyDischarged::Id);
}