Platform Driver
The Platform Driver agent is a special purpose agent a user can install on the platform to manage communication of the platform with devices. The Platform driver features a number of endpoints for collecting data and sending control signals using the message bus and automatically publishes data to the bus on a specified interval.
How does it work?
The Platform Driver creates a number of driver instances based on the contents of its config store; for each combination of driver configuration, registry configuration and other referenced config files, a driver instance is created by the Platform Driver. When configuration files are removed, the corresponding driver instance is removed by the Platform Driver.
Drivers are special-purpose agents for device communication, and unlike most agents, run as separate threads under the Platform Driver (typically agents are spawned as their own process). While running, the driver periodically “scrapes” device data and publishes the scrape to the message bus, as well as handling ad-hoc data collection and control signalling commands issued from the Platform Driver. The actual commands are issued to devices by the driver’s “Interface” class.
An Interface class is a Python class which serves as the interface between the driver and the device. The Interface does this by implementing a set of well-defined actions using the communication paradigms and protocols used by the device. For devices such as BACnet and Modbus devices, interfaces wrap certain protocol functions in Python code to be used by the driver. In other cases, interfaces interact with web-API’s, etc.
Device/Driver Communication
Device communication with the Platform Driver typically occurs using the following steps:
Platform agents and the user’s agents communicate between themselves and the message bus using publish/subscribe or JSON-RPC
The user’s agent sends a JSON-RPC request to the Platform Driver to get_point
And/Or the user’s agent sends a JSON-RPC request to the Actuator to set_point
The Platform Driver forwards the request to the driver instance specified in the request
The device driver communicates with the end device
The end device returns a response to the driver indicating its current status
The driver publishes the device’s response to the message bus using a publish
For more in-depth descriptions and coverage of atypical scenarios, read up on the driver communication patterns.
Configuration and Installation
Configuration for each device consists of 3 parts:
Platform Driver Agent configuration file - lists all driver configuration files to load
Driver configuration file - contains the general driver configuration and device settings
Device Register configuration file - contains the settings for each individual data point on the device
For each device, you must create a driver configuration file, device register configuration file, and an entry in the Platform Driver Agent configuration file.
Once configured, the Platform Driver Agent is configured and deployed in a manner similar to any other agent:
python scripts/install-agent.py -s services/core/PlatformDriverAgent -c <platform driver config file>
Requirements
VOLTTRON drivers operated by the platform driver may have additional requirements for installation. Required libraries:
BACnet driver - bacpypes
Modbus driver - pymodbus
Modbus_TK driver - modbus-tk
DNP3 and IEEE 2030.5 drivers - pydnp3
The easiest way to install the requirements for drivers included in the VOLTTRON repository is to use bootstrap.py
(see platform installation for more detail)
Platform Driver Configuration
The Platform Driver Agent configuration consists of general settings for all devices. The default values of the Platform Driver should be sufficient for most users. The user may optionally change the interval between device scrapes with the driver_scrape_interval.
The following example sets the driver_scrape_interval to 0.05 seconds or 20 devices per second:
{
"driver_scrape_interval": 0.05,
"publish_breadth_first_all": false,
"publish_depth_first": false,
"publish_breadth_first": false,
"publish_depth_first_all": true,
"group_offset_interval": 0.0
}
driver_scrape_interval - Sets the interval between devices scrapes. Defaults to 0.02 or 50 devices per second. Useful for when the platform scrapes too many devices at once resulting in failed scrapes.
group_offset_interval - Sets the interval between when groups of devices are scraped. Has no effect if all devices are in the same group.
In order to improve the scalability of the platform unneeded device state publishes for all devices can be turned off. All of the following setting are optional and default to True.
publish_depth_first_all - Enable “depth first” publish of all points to a single topic for all devices.
publish_breadth_first_all - Enable “breadth first” publish of all points to a single topic for all devices.
publish_depth_first - Enable “depth first” device state publishes for each register on the device for all devices.
publish_breadth_first - Enable “breadth first” device state publishes for each register on the device for all devices.
An example platform driver configuration file can be found in the VOLTTRON repository in services/core/PlatformDriverAgent/platform-driver.agent.
Driver Configuration File
Note
The terms register and point are used interchangeably in the documentation and in the configuration setting names. They have the same meaning in the context of VOLTTRON drivers.
Each device configuration has the following form:
{
"driver_config": {"device_address": "10.1.1.5",
"device_id": 500},
"driver_type": "bacnet",
"registry_config":"config://registry_configs/vav.csv",
"interval": 60,
"heart_beat_point": "heartbeat",
"group": 0
}
The following settings are required for all device configurations:
driver_config - Driver specific setting go here. See below for driver specific settings.
driver_type - Type of driver to use for this device: bacnet, modbus, fake, etc.
registry_config - Reference to a configuration file in the configuration store for registers on the device. See the Registry-Configuration-File section below and/or the Adding Device Configurations to the Configuration Store section in the driver framework docs.
These settings are optional:
interval - Period to scrape the device and publish the results in seconds. Defaults to 60 seconds.
heart_beat_point - A Point which to toggle to indicate a heartbeat to the device. A point with this
Volttron Point Name
must exist in the registry. If this setting is missing the driver will not send a heart beat signal to the device. Heart beats are triggered by the Actuator Agent which must be running to use this feature.group - Group this device belongs to. Defaults to 0
These settings are used to create the topic that this device will be referenced by following the VOLTTRON convention of
{campus}/{building}/{unit}
. This will also be the topic published on, when the device is periodically scraped for
its current state.
The topic used to reference the device is derived from the name of the device configuration in the store. See the Adding Device Configurations to the Configuration Store section of the driver framework docs.
Device Grouping
Devices may be placed into groups to separate them logically when they are scraped. This is done by setting the group in the device configuration. group is a number greater than or equal to 0. Only number of devices in the same group and the group_offset_interval are considered when determining when to scrape a device.
This is useful in two cases:
If you need to ensure that certain devices are scraped in close proximity to each other you can put them in their own group. If this causes devices to be scraped too quickly the groups can be separated out time wise using the group_offset_interval setting.
You may scrape devices on different networks in parallel for performance. For instance BACnet devices behind a single MSTP router need to be scraped slowly and serially, but devices behind different routers may be scraped in parallel. Grouping devices by router will do this automatically.
The group_offset_interval is applied by multiplying it by the group number. If you intend to use group_offset_interval only use consecutive group values that start with 0.
Registry Configuration File
Registry configuration files setup each individual point on a device. Typically this file will be in CSV format, but the exact format is driver specific. See the section for a particular driver for the registry configuration format.
The following is a simple example of a Modbus registry configuration file:
Reference Point Name |
Volttron Point Name |
Units |
Units Details |
Modbus Register |
Writable |
Point Address |
Default Value |
Notes |
---|---|---|---|---|---|---|---|---|
CO2Sensor |
ReturnAirCO2 |
PPM |
0.00-2000.00 |
>f |
FALSE |
1001 |
CO2 Reading 0.00-2000.0 ppm |
|
CO2Stpt |
ReturnAirCO2Stpt |
PPM |
1000.00 (default) |
>f |
TRUE |
1011 |
1000 |
Setpoint to enable demand control ventilation |
HeatCall2 |
HeatCall2 |
On / Off |
on/off |
BOOL |
FALSE |
1114 |
Status indicator of heating stage 2 need |
Adding Device Configurations to the Configuration Store
Configurations are added to the Configuration Store using the command line:
volttron-ctl config store platform.driver <name> <file name> <file type>
name - The name used to refer to the file from the store.
file name - A file containing the contents of the configuration.
file type -
--raw
,--json
, or--csv
. Indicates the type of the file. Defaults to--json
.
The main configuration must have the name config
Device configuration but not registry configurations must have a name prefixed with devices/
. Scripts that
automate the process will prefix registry configurations with registry_configs/
, but that is not a requirement for
registry files.
The name of the device’s configuration in the store is used to create the topic used to reference the device. For instance, a configuration named devices/PNNL/ISB1/vav1 will publish scrape results to devices/PNNL/ISB1/vav1 and is accessible with the Actuator Agent via PNNL/ISB1/vav1.
The name of a registry configuration must match the name used to refer to it in the driver configuration. The reference is not case sensitive.
If the Platform Driver Agent is running, any changes to the configuration store will immediately affect the running devices according to the changes.
Example
Consider the following three configuration files: A platform driver configuration called platform-driver.agent, a Modbus device configuration file called modbus_driver.config and corresponding Modbus registry configuration file called modbus_registry.csv
To store the platform driver configuration run the command:
volttron-ctl config store platform.driver config platform-driver.agent
To store the registry configuration run the command (note the --csv
option):
volttron-ctl config store platform.driver registry_configs/modbus_registry.csv modbus_registry.csv --csv
Note
The registry_configs/modbus_registry.csv argument in the above command must match the reference to the registry_config found in modbus_driver.config.
To store the driver configuration run the command:
volttron-ctl config store platform.driver devices/my_campus/my_building/my_device modbus_config.config
Converting Old Style Configuration
The new Platform Driver no longer supports the old style of device configuration. The old device_list setting is ignored.
To simplify updating to the new format, scripts/update_platform_driver_config.py is provided to automatically update to the new configuration format.
With the platform running run:
python scripts/update_platform_driver_config.py <old configuration> <output>
old_configuration is the main configuration file in the old format. The script automatically modifies the driver files to create references to CSV files and adds the CSV files with the appropriate name.
output is the target output directory.
If the --keep-old
switch is used, the old configurations in the output directory (if any) will not be deleted before
new configurations are created. Matching names will still be overwritten.
The output from scripts/update_platform_driver_config.py can be automatically added to the configuration store for the Platform Driver agent with scripts/install_platform_driver_configs.py.
Creating and naming configuration files in the form needed by scripts/install_platform_driver_configs.py can speed up
the process of changing and updating a large number of configurations. See the --help
message for
scripts/install_platform_driver_configs.py for more details.
Device Scalability Settings
To improve the scalability of the platform, unneeded device state publishes for a device can be turned off. All of the following setting are optional and will override the value set in the main platform driver configuration.
publish_depth_first_all - Enable “depth first” publish of all points to a single topic.
publish_breadth_first_all - Enable “breadth first” publish of all points to a single topic.
publish_depth_first - Enable “depth first” device state publishes for each register on the device.
publish_breadth_first - Enable “breadth first” device state publishes for each register on the device.
It is common practice to set publish_breadth_first_all, publish_depth_first, and publish_breadth_first to False unless they are specifically needed by an agent running on the platform.
Note
All Historian Agents require publish_depth_first_all to be set to True in order to capture data.
Usage
After installing the Platform Driver and loading driver configs into the config store, the installed drivers begin polling and JSON-RPC endpoints become usable.
Polling
Once running, the Platform Driver will spawn drivers using the driver_type parameter of the driver configuration and periodically poll devices for all point data specified in the registry configuration at the interval specified by the interval parameter of the driver configuration.
By default, the value of each register on a device is published 4 different ways when the device state is published.
Consider the following settings in a driver configuration stored under the name devices/pnnl/isb1/vav1
:
{
"driver_config": {"device_address": "10.1.1.5",
"device_id": 500},
"driver_type": "bacnet",
"registry_config":"config://registry_configs/vav.csv",
}
In the vav.csv file, a register has the name temperature. For these examples the current value of the register on the device happens to be 75.2 and the meta data is
{"units": "F"}
When the driver publishes the device state the following two things will be published for this register:
A “depth first” publish to the topic devices/pnnl/isb1/vav1/temperature with the following message:
[75.2, {"units": "F"}]A “breadth first” publish to the topic devices/temperature/vav1/isb1/pnnl with the following message:
[75.2, {"units": "F"}]These publishes can be turned off by setting publish_depth_first and publish_breadth_first to false respectively.
Also these two publishes happen once for all registers:
A “depth first” publish to the topic devices/pnnl/isb1/vav1/all with the following message:
[{"temperature": 75.2, ...}, {"temperature":{"units": "F"}, ...}]A “breadth first” publish to the topic devices/all/vav1/isb1/pnnl with the following message:
[{"temperature": 75.2, ...}, {"temperature":{"units": "F"}, ...}]These publishes can be turned off by setting publish_depth_first_all and publish_breadth_first_all to
false
respectively.
JSON-RPC Endpoints
get_point - Returns the value of specified device set point
- Parameters
path - device topic string (typical format is devices/campus/building/device)
point_name - name of device point from registry configuration file
- set_point - Set value on specified device set point. If global override is condition is set, raise OverrideError
exception.
- Parameters
path - device topic string (typical format is devices/campus/building/device)
point_name - name of device point from registry configuration file
value - desired value to set for point on device
Warning
It is not recommended to call the set_point method directly. It is recommended to instead use the Actuator agent to set points on a device, using its scheduling capability.
scrape_all - Returns values for all set points on the specified device.
- Parameters
path - device topic string (typical format is devices/campus/building/device)
get_multiple_points - return values corresponding to multiple points on the same device
- Parameters
path - device topic string (typical format is devices/campus/building/device)
point_names - iterable of device point names from registry configuration file
- set_multiple_points - Set values on multiple set points at once. If global override is condition is set, raise
OverrideError exception.
- Parameters
path - device topic string (typical format is devices/campus/building/device)
point_names_value - list of tuples consisting of (point_name, value) pairs for setting a series of points
heart_beat - Send a heartbeat/keep-alive signal to all devices configured for Platform Driver
- revert_point - Revert the set point of a device to its default state/value. If global override is condition is
set, raise OverrideError exception.
- Parameters
path - device topic string (typical format is devices/campus/building/device)
point_name - name of device point from registry configuration file
- revert_device - Revert all the set point values of the device to default state/values. If global override is
condition is set, raise OverrideError exception.
- Parameters
path - device topic string (typical format is devices/campus/building/device)
- set_override_on - Turn on override condition on all the devices matching the specified pattern (
-
- Parameters
- pattern - Override pattern to be applied. For example,
If pattern is campus/building1/* - Override condition is applied for all the devices under campus/building1/.
If pattern is campus/building1/ahu1 - Override condition is applied for only campus/building1/ahu1 The pattern matching is based on bash style filename matching semantics.
duration - Duration in seconds for the override condition to be set on the device (default 0.0, duration <= 0.0 imply indefinite duration)
failsafe_revert - Flag to indicate if all the devices falling under the override condition must to be set to its default state/value immediately.
staggered_revert -
set_override_off - Turn off override condition on all the devices matching the pattern.
- Parameters
pattern - device topic pattern for devices on which the override condition should be removed.
get_override_devices - Get a list of all the devices with override condition.
clear_overrides - Turn off override condition for all points on all devices.
get_override_patterns - Get a list of all override condition patterns currently set.
Driver Override Condition
By default, every user is allowed write access to the devices by the platform driver. The override feature will allow the user (for example, building administrator) to override this default behavior and enable the user to lock the write access on the devices for a specified duration of time or indefinitely.
Set Override On
The Platform Driver’s set_override_on
RPC method can be used to set the override condition for all drivers with topic
matching the provided pattern. This can be specific devices, groups of devices, or even all configured devices. The
pattern matching is based on bash style filename matching semantics.
Parameters:
- pattern: Override pattern to be applied. For example,
If the pattern is
campus/building1/*
the override condition is applied for all the devices under campus/building1/.If the pattern is
campus/building1/ahu1
the override condition is applied for only the campus/building1/ahu1 device. The pattern matching is based on bash style filename matching semantics.duration: Time duration for the override in seconds. If duration <= 0.0, it implies an indefinite duration.
failsafe_revert: Flag to indicate if all the devices falling under the override condition has to be set to its default state/value immediately.
staggered_revert: If this flag is set, reverting of devices will be staggered.
Example set_override_on
RPC call:
self.vip.rpc.call(PLATFORM_DRIVER, "set_override_on", <override pattern>, <override duration>)
Set Override Off
The override condition can also be toggled off based on a provided pattern using the Platform Driver’s
set_override_off
RPC call.
Parameters:
- pattern: Override pattern to be applied. For example,
If the pattern is
campus/building1/*
the override condition is removed for all the devices under campus/building1/.If the pattern is
campus/building1/ahu1
the override condition is removed for only for the campus/building1/ahu1 device. The pattern matching is based on bash style filename matching semantics.
Example set_override_off
RPC call:
self.vip.rpc.call(PLATFORM_DRIVER, "set_override_off", <override pattern>)
Get Override Devices
A list of all overridden devices can be obtained with the Platform Driver’s get_override_devices
RPC call.
This method call has no additional parameters.
Example get_override_devices
RPC call:
self.vip.rpc.call(PLATFORM_DRIVER, "get_override_devices")
Get Override Patterns
A list of all patterns which have been requested for override can be obtained with the Platform Driver’s
get_override_patterns
RPC call.
This method call has no additional parameters
Example “get_override_patterns” RPC call:
self.vip.rpc.call(PLATFORM_DRIVER, "get_override_patterns")
Clear Overrides
All overrides set by RPC calls described above can be toggled off at using a single clear_overrides
RPC call.
This method call has no additional parameters
Example “clear_overrides” RPC call:
self.vip.rpc.call(PLATFORM_DRIVER, "clear_overrides")
For information on the global override feature specification, view the Global Override Specification doc.