An example showing the use of CHIP on the Linux. The document will describe how to build and run CHIP Linux Energy Management Example on Raspberry Pi. This doc is tested on Ubuntu for Raspberry Pi Server 20.04 LTS (aarch64) and Ubuntu for Raspberry Pi Desktop 20.10 (aarch64)
To cross-compile this example on x64 host and run on NXP i.MX 8M Mini EVK, see the associated README document for details.
Install tool chain
$ sudo apt-get install git gcc g++ python pkg-config libssl-dev libdbus-1-dev libglib2.0-dev ninja-build python3-venv python3-dev unzip
Build the example application:
$ cd ~/connectedhomeip/examples/energy-management-app/linux $ git submodule update --init $ source third_party/connectedhomeip/scripts/activate.sh $ gn gen out/debug $ ninja -C out/debug
To delete generated executable, libraries and object files use:
$ cd ~/connectedhomeip/examples/energy-management-app/linux $ rm -rf out/
Build the example with pigweed RPC
$ cd ~/connectedhomeip/examples/energy-management-app/linux $ git submodule update --init $ source third_party/connectedhomeip/scripts/activate.sh $ gn gen out/debug --args='import("//with_pw_rpc.gni")' $ ninja -C out/debug
--wifi
Enables WiFi management feature. Required for WiFi commissioning.
--thread
Enables Thread management feature, requires ot-br-posix dbus daemon running. Required for Thread commissioning.
--ble-device <interface id>
Use specific bluetooth interface for BLE advertisement and connections.
interface id
: the number after hci
when listing BLE interfaces by hciconfig
command, for example, --ble-device 1
means using hci1
interface. Default: 0
.
--application <evse | water-heater>
Emulate either an EVSE or Water Heater example.
--featureSet <feature map for Device Energy Management e.g. 0x7a>
Sets the run-time FeatureMap value for the Device Energy Management cluster. This allows the DEM cluster to support PFR
or SFR
so that the full range of TC_DEM_2.x test cases can be exercised with this application.
See the test-runner headers in the respective test script in src/python_testing/TC_DEM_2.x.py which have recommended values to use.
If you want to test Echo protocol, please enable Echo handler
gn gen out/debug --args='chip_app_use_echo=true' ninja -C out/debug
Prerequisites
pi-bluetooth
via APT.Building
Follow Building section of this document.
Running
[Optional] Plug USB Bluetooth dongle
Plug USB Bluetooth dongle and find its bluetooth device number. The number after hci
is the bluetooth device number, 1
in this example.
$ hciconfig hci1: Type: Primary Bus: USB BD Address: 00:1A:7D:AA:BB:CC ACL MTU: 310:10 SCO MTU: 64:8 UP RUNNING PSCAN ISCAN RX bytes:20942 acl:1023 sco:0 events:1140 errors:0 TX bytes:16559 acl:1011 sco:0 commands:121 errors:0 hci0: Type: Primary Bus: UART BD Address: B8:27:EB:AA:BB:CC ACL MTU: 1021:8 SCO MTU: 64:1 UP RUNNING PSCAN ISCAN RX bytes:8609495 acl:14 sco:0 events:217484 errors:0 TX bytes:92185 acl:20 sco:0 commands:5259 errors:0
Run Linux Energy Management Example App
$ cd ~/connectedhomeip/examples/energy-management-app/linux $ sudo out/debug/chip-energy-management-app --ble-device [bluetooth device number] # In this example, the device we want to use is hci1 $ sudo out/debug/chip-energy-management-app --ble-device 1
Test the device using ChipDeviceController on your laptop / workstation etc.
Device tracing is available to analyze the device performance. To turn on tracing, build with RPC enabled. See Building with RPC enabled.
Obtain tracing json file.
$ ./{PIGWEED_REPO}/pw_trace_tokenized/py/pw_trace_tokenized/get_trace.py -s localhost:33000 \ -o {OUTPUT_FILE} -t {ELF_FILE} {PIGWEED_REPO}/pw_trace_tokenized/pw_trace_protos/trace_rpc.proto
When you want to test this cluster you can use chip-repl or chip-tool by hand. CHIP-REPL is slightly easier to interact with when dealing with some of the complex structures.
There are several test scripts provided for EVSE (in src/python_testing):
TC_EEVSE_2_2
: This validates the primary functionalityTC_EEVSE_2_3
: This validates Get/Set/Clear target commandsTC_EEVSE_2_4
: This validates FaultsTC_EEVSE_2_5
: This validates EVSE diagnostic command (optional)TC_EEVSE_2_6
: This validates EVSE Forecast Adjustment with State Forecast Reporting feature functionalityTC_EEVSE_2_7
: This validates EVSE Constraints-based Adjustment with Power Forecast Reporting feature functionalityTC_EEVSE_2_8
: This validates EVSE Constraints-based Adjustment with State Forecast Reporting feature functionalityTC_EEVSE_2_9
: This validates EVSE Power or State Forecast Reporting feature functionalityThese scripts require the use of Test Event Triggers via the GeneralDiagnostics cluster on Endpoint 0. This requires an enableKey
(16 bytes) and a set of reserved int64_t test event trigger codes.
By default the test event support is not enabled, and when compiling the example app you need to add chip_enable_energy_evse_trigger=true
to the gn args.
$ gn gen out/debug --args='chip_enable_energy_evse_trigger=true' $ ninja -C out/debug
Once the application is built you also need to tell it at runtime what the chosen enable key is using the --enable-key
command line option.
$ ./chip-energy-management-app --enable-key 000102030405060708090a0b0c0d0e0f --application evse
From the top-level of the connectedhomeip repo type:
Start the chip-energy-management-app:
rm -f evse.bin; out/debug/chip-energy-management-app --enable-key 000102030405060708090a0b0c0d0e0f --KVS evse.bin --featureSet $featureSet --application evse
where the $featureSet depends on the test being run:
TC_DEM_2_2.py: 0x01 // PA TC_DEM_2_3.py: 0x3b // STA, PAU, FA, CON + (PFR | SFR) TC_DEM_2_4.py: 0x3b // STA, PAU, FA, CON + (PFR | SFR) TC_DEM_2_5.py: 0x3b // STA, PAU, FA, CON + PFR TC_DEM_2_6.py: 0x3d // STA, PAU, FA, CON + SFR TC_DEM_2_7.py: 0x3b // STA, PAU, FA, CON + PFR TC_DEM_2_8.py: 0x3d // STA, PAU, FA, CON + SFR TC_DEM_2_9.py: 0x3f // STA, PAU, FA, CON + PFR + SFR
where
PA - DEM.S.F00(PowerAdjustment) PFR - DEM.S.F01(PowerForecastReporting) SFR - DEM.S.F02(StateForecastReporting) STA - DEM.S.F03(StartTimeAdjustment) PAU - DEM.S.F04(Pausable) FA - DEM.S.F05(ForecastAdjustment) CON -DEM.S.F06(ConstraintBasedAdjustment)
Then run the test:
$ python src/python_testing/TC_EEVSE_2_2.py --endpoint 1 -m on-network -n 1234 -p 20202021 -d 3840 --hex-arg enableKey:000102030405060708090a0b0c0d0e0f
--endpoint 1
must be used with the example, since the EVSE cluster is on endpoint 1. The --hex-arg enableKey:<key>
value must match the --enable-key <key>
used on chip-energy-management-app args.The chip-energy-management-app will need to be stopped before running each test script as each test commissions the chip-energy-management-app in the first step. That is also why the evse.bin is deleted before running chip-energy-management-app as this is where the app stores the matter persistent data (e.g. fabric info).
$ ./build_python.sh -i <path_to_out_folder>
$ source <path_to_out_folder>/bin/activate
$ ./chip-energy-management-app --enable-key 000102030405060708090a0b0c0d0e0f --application evse
$ chip-repl
await devCtrl.CommissionOnNetwork(1234,20202021) # Commission with NodeID 1234 Established secure session with Device Commissioning complete Out[2]: <chip.native.PyChipError object at 0x7f2432b16140>
# Read from NodeID 1234, Endpoint 1, all attributes on EnergyEvse cluster await devCtrl.ReadAttribute(1234,[(1, chip.clusters.EnergyEvse)])
{ │ 1: { │ │ <class 'chip.clusters.Objects.EnergyEvse'>: { │ │ │ <class 'chip.clusters.Attribute.DataVersion'>: 3790455237, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.ChargingEnabledUntil'>: Null, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.FaultState'>: <FaultStateEnum.kNoError: 0>, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.NextChargeStartTime'>: Null, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.StateOfCharge'>: Null, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.MaximumChargeCurrent'>: 0, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.ApproximateEVEfficiency'>: Null, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.BatteryCapacity'>: Null, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.AcceptedCommandList'>: [ ... │ │ ], │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.MinimumChargeCurrent'>: 6000, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.NextChargeTargetSoC'>: Null, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.SessionDuration'>: 758415333, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.NumberOfWeeklyTargets'>: 0, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.FeatureMap'>: 1, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.GeneratedCommandList'>: [ ... │ │ │ ], │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.State'>: <StateEnum.kNotPluggedIn: 0>, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.SessionID'>: Null, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.SessionEnergyCharged'>: Null, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.VehicleID'>: Null, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.NextChargeRequiredEnergy'>: Null, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.SessionEnergyDischarged'>: Null, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.AttributeList'>: [ ... │ │ ], │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.NextChargeTargetTime'>: Null, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.CircuitCapacity'>: 0, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.DischargingEnabledUntil'>: Null, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.SupplyState'>: <SupplyStateEnum.kDisabled: 0>, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.RandomizationDelayWindow'>: 600, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.MaximumDischargeCurrent'>: 0, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.NumberOfDailyTargets'>: 1, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.UserMaximumChargeCurrent'>: 80000, │ │ │ <class 'chip.clusters.Objects.EnergyEvse.Attributes.ClusterRevision'>: 2 │ │ } │ } }
reportingTimingParams = (3, 60) # MinInterval = 3s, MaxInterval = 60s subscription = await devCtrl.ReadAttribute(1234,[(1, chip.clusters.EnergyEvse)], reportInterval=reportingTimingParams)
EnableCharging
command which lasts for 60 seconds The EnableCharging
takes an optional chargingEnabledUntil
parameter which allows the charger to automatically disable itself at some preset time in the future. Note that it uses Epoch_s (which is from Jan 1 2000) which is a uint32_t in seconds.from datetime import datetime, timezone, timedelta epoch_end = int((datetime.now(tz=timezone.utc) + timedelta(seconds=60) - datetime(2000, 1, 1, 0, 0, 0, 0, timezone.utc)).total_seconds()) await devCtrl.SendCommand(1234, 1, chip.clusters.EnergyEvse.Commands.EnableCharging(chargingEnabledUntil=epoch_end,minimumChargeCurrent=2000,maximumChargeCurrent=25000),timedRequestTimeoutMs=3000)
The output should look like:
Attribute Changed: { │ 'Endpoint': 1, │ 'Attribute': <class 'chip.clusters.Objects.EnergyEvse.Attributes.SupplyState'>, │ 'Value': <SupplyStateEnum.kChargingEnabled: 1> } Attribute Changed: { │ 'Endpoint': 1, │ 'Attribute': <class 'chip.clusters.Objects.EnergyEvse.Attributes.MinimumChargeCurrent'>, │ 'Value': 2000 } Attribute Changed: { │ 'Endpoint': 1, │ 'Attribute': <class 'chip.clusters.Objects.EnergyEvse.Attributes.ChargingEnabledUntil'>, │ 'Value': 758416066 }
After 60 seconds the charging should automatically become disabled:
Attribute Changed: { │ 'Endpoint': 1, │ 'Attribute': <class 'chip.clusters.Objects.EnergyEvse.Attributes.SupplyState'>, │ 'Value': <SupplyStateEnum.kDisabled: 0> } Attribute Changed: { │ 'Endpoint': 1, │ 'Attribute': <class 'chip.clusters.Objects.EnergyEvse.Attributes.DischargingEnabledUntil'>, │ 'Value': 0 } Attribute Changed: { │ 'Endpoint': 1, │ 'Attribute': <class 'chip.clusters.Objects.EnergyEvse.Attributes.MinimumChargeCurrent'>, │ 'Value': 0 } Attribute Changed: { │ 'Endpoint': 1, │ 'Attribute': <class 'chip.clusters.Objects.EnergyEvse.Attributes.ChargingEnabledUntil'>, │ 'Value': 0 }
Note that you can omit the chargingEnabledUntil
argument and it will charge indefinitely.
If you haven't implemented a real EVSE but want to simulate plugging in an EV then you can use a few of the test event triggers to simulate these scenarios.
The test event triggers values can be found in: EnergyEvseTestEventTriggerHandler.h
EVConnected
event)To send a test event trigger to the app, use the following commands (in chip-repl):
# send 1st event trigger to 'install' the EVSE on a 32A supply await devCtrl.SendCommand(1234, 0, chip.clusters.GeneralDiagnostics.Commands.TestEventTrigger(enableKey=bytes([b for b in range(16)]), eventTrigger=0x0099000000000000)) # send 2nd event trigger to plug the EV in await devCtrl.SendCommand(1234, 0, chip.clusters.GeneralDiagnostics.Commands.TestEventTrigger(enableKey=bytes([b for b in range(16)]), eventTrigger=0x0099000000000002))
Now send the enable charging command (omit the chargingEnabledUntil
arg this time):
await devCtrl.SendCommand(1234, 1, chip.clusters.EnergyEvse.Commands.EnableCharging(minimumChargeCurrent=2000,maximumChargeCurrent=25000),timedRequestTimeoutMs=3000)
Now send the test event trigger to simulate the EV asking for demand:
# send 2nd event trigger to plug the EV in await devCtrl.SendCommand(1234, 0, chip.clusters.GeneralDiagnostics.Commands.TestEventTrigger(enableKey=bytes([b for b in range(16)]), eventTrigger=0x0099000000000004)) # Read the events await devCtrl.ReadEvent(1234,[(1, chip.clusters.EnergyEvse,1)])
[ │ EventReadResult( │ │ Header=EventHeader( │ │ │ EndpointId=1, │ │ │ ClusterId=153, │ │ │ EventId=0, │ │ │ EventNumber=65538, │ │ │ Priority=<EventPriority.INFO: 1>, │ │ │ Timestamp=1705102500069, │ │ │ TimestampType=<EventTimestampType.EPOCH: 1> │ │ ), │ │ Status=<Status.Success: 0>, │ │ Data=EVConnected( │ │ │ sessionID=0 │ │ ) │ ), │ EventReadResult( │ │ Header=EventHeader( │ │ │ EndpointId=1, │ │ │ ClusterId=153, │ │ │ EventId=2, │ │ │ EventNumber=65539, │ │ │ Priority=<EventPriority.INFO: 1>, │ │ │ Timestamp=1705102801764, │ │ │ TimestampType=<EventTimestampType.EPOCH: 1> │ │ ), │ │ Status=<Status.Success: 0>, │ │ Data=EnergyTransferStarted( │ │ │ sessionID=0, │ │ │ state=<StateEnum.kPluggedInCharging: 3>, │ │ │ maximumCurrent=25000 │ │ ) │ ) ]
EventNumber 65538
was sent when the vehicle was plugged in, and a new sessionID=0
was created.EnergyTransferStarted
was sent in EventNumber 65539
What happens when we unplug the vehicle?
await devCtrl.SendCommand(1234, 0, chip.clusters.GeneralDiagnostics.Commands.TestEventTrigger(enableKey=bytes([b for b in range(16)]), eventTrigger=0x0099000000000001))
When we re-read the events:
[ │ EventReadResult( │ │ Header=EventHeader( │ │ │ EndpointId=1, │ │ │ ClusterId=153, │ │ │ EventId=3, │ │ │ EventNumber=65540, │ │ │ Priority=<EventPriority.INFO: 1>, │ │ │ Timestamp=1705102996749, │ │ │ TimestampType=<EventTimestampType.EPOCH: 1> │ │ ), │ │ Status=<Status.Success: 0>, │ │ Data=EnergyTransferStopped( │ │ │ sessionID=0, │ │ │ state=<StateEnum.kPluggedInCharging: 3>, │ │ │ reason=<EnergyTransferStoppedReasonEnum.kOther: 2>, │ │ │ energyTransferred=0 │ │ ) │ ), │ EventReadResult( │ │ Header=EventHeader( │ │ │ EndpointId=1, │ │ │ ClusterId=153, │ │ │ EventId=1, │ │ │ EventNumber=65541, │ │ │ Priority=<EventPriority.INFO: 1>, │ │ │ Timestamp=1705102996749, │ │ │ TimestampType=<EventTimestampType.EPOCH: 1> │ │ ), │ │ Status=<Status.Success: 0>, │ │ Data=EVNotDetected( │ │ │ sessionID=0, │ │ │ state=<StateEnum.kPluggedInCharging: 3>, │ │ │ sessionDuration=0, │ │ │ sessionEnergyCharged=0, │ │ │ sessionEnergyDischarged=0 │ │ ) │ ) ]
In EventNumber 65540
we had an EnergyTransferStopped
event with reason kOther
.
This was a rather abrupt end to a charging session (normally we would see the EVSE or EV decide to stop charging), but this demonstrates the cable being pulled out without a graceful charging shutdown.
In EventNumber 65541
we had an EvNotDetected
event showing that the state was kPluggedInCharging
prior to the EV being not detected (normally in a graceful shutdown this would be kPluggedInNoDemand
or kPluggedInDemand
).
This section demonstrates how to run the Water Heater application and interact with it using the chip-tool
and TestEventTriggers
. By default (at the time of writing), the WaterHeater app does not configure some of its attributes with simulated values (most default to 0). The steps below set the default TestEventTrigger
which Simulate installation in a 100L tank full of water at 20C, with a target temperature of 60C, in OFF mode
.
Step-by-step:
Build the energy-management-app
for linux:
./scripts/build/build_examples.py --target linux-x64-energy-management-no-ble build
Run the Water Heater application:
rm /tmp/chip_* && ./out/linux-x64-energy-management-no-ble/chip-energy-management-app --application water-heater --trace-to json:log --enable-key 000102030405060708090a0b0c0d0e0f
Commission with chip-tool as node 0x12344321
:
./out/linux-x64-chip-tool-no-ble/chip-tool pairing code 0x12344321 MT:-24J0AFN00KA0648G00
Read the TankVolume
attribute (expect 0 by default):
./out/linux-x64-chip-tool-no-ble/chip-tool waterheatermanagement read tank-volume 0x12344321 2 | grep TOO [1730306361.511] [2089549:2089552] [TOO] TankVolume: 0
Set the default TestEventTrigger (0x0094000000000000
):
0x0094000000000000
corresponds to kBasicInstallationTestEvent
from WaterHeadermanagementTestEventTriggerHandler.h
hex:00010203...0e0f
is the --enable-key
passed to the startup of chip-energy-management-app0x12344321
is the node-id that the app was commissioned on0
is the endpoint on which the GeneralDiagnostics
cluster exists to call the TestEventTrigger
command./out/linux-x64-chip-tool-no-ble/chip-tool generaldiagnostics test-event-trigger hex:000102030405060708090a0b0c0d0e0f 0x0094000000000000 0x12344321 0
Read TankVolume attribute again (now expect 100):
./out/linux-x64-chip-tool-no-ble/chip-tool waterheatermanagement read tank-volume 0x12344321 2 | grep TOO [1730312762.703] [2153606:2153609] [TOO] TankVolume: 100
Set boost state:
durationIndicates
the time period in seconds for which the BOOST state is activated before it automatically reverts to the previous mode (e.g. OFF, MANUAL or TIMED)../out/linux-x64-chip-tool-no-ble/chip-tool waterheatermanagement boost '{ "duration": 1800 }' 0x12344321 2
Cancel boost state:
./out/linux-x64-chip-tool-no-ble/chip-tool waterheatermanagement cancel-boost 0x12344321 2