A flexible and robust Python library for creating, managing, and interacting with data services, with built-in support for web and RPC servers, and customizable features for diverse use cases.
Project description
pydase (Python Data Service)
pydase
is a Python library for creating data service servers with integrated web and RPC servers. It's designed to handle the management of data structures, automated tasks, and callbacks, and provides built-in functionality for serving data over different protocols.
- Features
- Installation
- Usage
- Understanding the Component System
- Understanding Service Persistence
- Understanding Tasks in pydase
- Understanding Units in pydase
- Changing the Log Level
- Documentation
- Contributing
- License
Features
- Simple data service definition through class-based interface
- Integrated web interface for interactive access and control of your data service
- Support for
rpyc
connections, allowing for programmatic control and interaction with your service - Component system bridging Python backend with frontend visual representation
- Saving and restoring the service state for service persistence
- Automated task management with built-in start/stop controls and optional autostart
- Support for units
Installation
Install pydase using poetry
:
poetry add pydase
or pip
:
pip install pydase
Usage
Using pydase
involves three main steps: defining a DataService
subclass, running the server, and then connecting to the service either programmatically using rpyc
or through the web interface.
Defining a DataService
To use pydase, you'll first need to create a class that inherits from DataService
. This class represents your custom data service, which will be exposed via RPC (using rpyc) and a web server. Your class can implement class / instance attributes and synchronous and asynchronous tasks.
Here's an example:
from pydase import DataService, Server
class Device(DataService):
_current = 0.0
_voltage = 0.0
_power = False
@property
def current(self) -> float:
# run code to get current
return self._current
@current.setter
def current(self, value: float) -> None:
# run code to set current
self._current = value
@property
def voltage(self) -> float:
# run code to get voltage
return self._voltage
@voltage.setter
def voltage(self, value: float) -> None:
# run code to set voltage
self._voltage = value
@property
def power(self) -> bool:
# run code to get power state
return self._power
@power.setter
def power(self, value: bool) -> None:
# run code to set power state
self._power = value
def reset(self) -> None:
self.current = 0.0
self.voltage = 0.0
if __name__ == "__main__":
service = Device()
Server(service).run()
In the above example, we define a Device class that extends DataService. We define a few properties (current, voltage, power) and their getter and setter methods.
Running the Server
Once your DataService is defined, you can create an instance of it and run the server:
from pydase import Server
# ... defining the Device class ...
if __name__ == "__main__":
service = Device()
Server(service).run()
This will start the server, making your Device service accessible via RPC and a web server at http://localhost:8001.
Accessing the Web Interface
Once the server is running, you can access the web interface in a browser:
In this interface, you can interact with the properties of your Device
service.
Connecting to the Service using rpyc
You can also connect to the service using rpyc
. Here's an example on how to establish a connection and interact with the service:
import rpyc
# Connect to the service
conn = rpyc.connect("<ip_addr>", 18871)
client = conn.root
# Interact with the service
client.voltage = 5.0
print(client.voltage) # prints 5.0
In this example, replace <ip_addr>
with the IP address of the machine where the service is running. After establishing a connection, you can interact with the service attributes as if they were local attributes.
Understanding the Component System
In pydase
, components are fundamental building blocks that bridge the Python backend logic with frontend visual representation and interactions. This system can be understood based on the following categories:
Built-in Type and Enum Components
pydase
automatically maps standard Python data types to their corresponding frontend components:
str
: Translated into aStringComponent
on the frontend.int
andfloat
: Manifested as theNumberComponent
.bool
: Rendered as aButtonComponent
.list
: Each item displayed individually, named after the list attribute and its index.enum.Enum
: Presented as anEnumComponent
, facilitating dropdown selection.
Method Components
Methods within the DataService
class have frontend representations:
- Regular Methods: These are rendered as a
MethodComponent
in the frontend, allowing users to execute the method via an "execute" button. - Asynchronous Methods: These are manifested as the
AsyncMethodComponent
with "start"/"stop" buttons to manage the execution of tasks.
DataService Instances (Nested Classes)
Nested DataService
instances offer an organized hierarchy for components, enabling richer applications. Each nested class might have its own attributes and methods, each mapped to a frontend component.
Here is an example:
from pydase import DataService, Server
class Channel(DataService):
def __init__(self, channel_id: int) -> None:
self._channel_id = channel_id
self._current = 0.0
super().__init__()
@property
def current(self) -> float:
# run code to get current
result = self._current
return result
@current.setter
def current(self, value: float) -> None:
# run code to set current
self._current = value
class Device(DataService):
def __init__(self) -> None:
self.channels = [Channel(i) for i in range(2)]
super().__init__()
if __name__ == "__main__":
service = Device()
Server(service).run()
Note that defining classes within DataService
classes is not supported (see this issue).
Custom Components (pydase.components
)
The custom components in pydase
have two main parts:
- A Python Component Class in the backend, implementing the logic needed to set, update, and manage the component's state and data.
- A Frontend React Component that renders and manages user interaction in the browser.
Below are the components available in the pydase.components
module, accompanied by their Python usage:
Image
This component provides a versatile interface for displaying images within the application. Users can update and manage images from various sources, including local paths, URLs, and even matplotlib figures.
The component offers methods to load images seamlessly, ensuring that visual content is easily integrated and displayed within the data service.
import matplotlib.pyplot as plt
import numpy as np
import pydase
from pydase.components.image import Image
class MyDataService(pydase.DataService):
my_image = Image()
if __name__ == "__main__":
service = MyDataService()
# loading from local path
service.my_image.load_from_path("/your/image/path/")
# loading from a URL
service.my_image.load_from_url("https://cataas.com/cat")
# loading a matplotlib figure
fig = plt.figure()
x = np.linspace(0, 2 * np.pi)
plt.plot(x, np.sin(x))
plt.grid()
service.my_image.load_from_matplotlib_figure(fig)
pydase.Server(service).run()
NumberSlider
This component provides an interactive slider interface for adjusting numerical values on the frontend. It supports both floats and integers. The values adjusted on the frontend are synchronized with the backend in real-time, ensuring consistent data representation.
The slider can be customized with initial values, minimum and maximum limits, and step sizes to fit various use cases.
import pydase
from pydase.components import NumberSlider
class MyService(pydase.DataService):
slider = NumberSlider(value=3.5, min=0, max=10, step_size=0.1, type="float")
if __name__ == "__main__":
service = MyService()
pydase.Server(service).run()
ColouredEnum
This component provides a way to visually represent different states or categories in a data service using colour-coded options. It behaves similarly to a standard Enum
, but the values encode colours in a format understood by CSS. The colours can be defined using various methods like Hexadecimal, RGB, HSL, and more.
If the property associated with the ColouredEnum
has a setter function, the keys of the enum will be rendered as a dropdown menu, allowing users to interact and select different options. Without a setter function, the selected key will simply be displayed as a coloured box with text inside, serving as a visual indicator.
import pydase
import pydase.components as pyc
class MyStatus(pyc.ColouredEnum):
PENDING = "#FFA500" # Hexadecimal colour (Orange)
RUNNING = "#0000FF80" # Hexadecimal colour with transparency (Blue)
PAUSED = "rgb(169, 169, 169)" # RGB colour (Dark Gray)
RETRYING = "rgba(255, 255, 0, 0.3)" # RGB colour with transparency (Yellow)
COMPLETED = "hsl(120, 100%, 50%)" # HSL colour (Green)
FAILED = "hsla(0, 100%, 50%, 0.7)" # HSL colour with transparency (Red)
CANCELLED = "SlateGray" # Cross-browser colour name (Slate Gray)
class StatusTest(pydase.DataService):
_status = MyStatus.RUNNING
@property
def status(self) -> MyStatus:
return self._status
@status.setter
def status(self, value: MyStatus) -> None:
# do something ...
self._status = value
# Modifying or accessing the status value:
my_service = StatusExample()
my_service.status = MyStatus.FAILED
Extending with New Components
Users can also extend the library by creating custom components. This involves defining the behavior on the Python backend and the visual representation on the frontend. For those looking to introduce new components, the guide on adding components provides detailed steps on achieving this.
Understanding Service Persistence
pydase
allows you to easily persist the state of your service by saving it to a file. This is especially useful when you want to maintain the service's state across different runs.
To save the state of your service, pass a filename
keyword argument to the __init__
method of the DataService
base class. If the file specified by filename
does not exist, the service will create this file and store its state in it when the service is shut down. If the file already exists, the service will load the state from this file, setting the values of its attributes to the values stored in the file.
Here's an example:
from pydase import DataService, Server
class Device(DataService):
def __init__(self, filename: str) -> None:
# ... your init code ...
# Pass the filename argument to the parent class
super().__init__(filename=filename)
# ... defining the Device class ...
if __name__ == "__main__":
service = Device("device_state.json")
Server(service).run()
In this example, the state of the Device
service will be saved to device_state.json
when the service is shut down. If device_state.json
exists when the service is started, the service will restore its state from this file.
Note: If the service class structure has changed since the last time its state was saved, only the attributes that have remained the same will be restored from the settings file.
Understanding Tasks in pydase
In pydase
, a task is defined as an asynchronous function contained in a class that inherits from DataService
. These tasks usually contain a while loop and are designed to carry out periodic functions.
For example, a task might be used to periodically read sensor data, update a database, or perform any other recurring job. The core feature of pydase
is its ability to automatically generate start and stop functions for these tasks. This allows you to control task execution via both the frontend and an rpyc
client, giving you flexible and powerful control over your service's operation.
Another powerful feature of pydase
is its ability to automatically start tasks upon initialization of the service. By specifying the tasks and their arguments in the _autostart_tasks
dictionary in your service class's __init__
method, pydase
will automatically start these tasks when the server is started. Here's an example:
from pydase import DataService, Server
class SensorService(DataService):
def __init__(self):
self.readout_frequency = 1.0
self._autostart_tasks = {"read_sensor_data": ()} # args passed to the function go there
super().__init__()
def _process_data(self, data: ...) -> None:
...
def _read_from_sensor(self) -> Any:
...
async def read_sensor_data(self):
while True:
data = self._read_from_sensor()
self._process_data(data) # Process the data as needed
await asyncio.sleep(self.readout_frequency)
if __name__ == "__main__":
service = SensorService()
Server(service).run()
In this example, read_sensor_data
is a task that continuously reads data from a sensor. The readout frequency can be updated using the readout_frequency
attribute.
By listing it in the _autostart_tasks
dictionary, it will automatically start running when Server(service).run()
is executed.
As with all tasks, pydase
will also generate start_read_sensor_data
and stop_read_sensor_data
methods, which can be called to manually start and stop the data reading task.
Understanding Units in pydase
pydase
integrates with the pint
package to allow you to work with physical quantities within your service. This enables you to define attributes with units, making your service more expressive and ensuring consistency in the handling of physical quantities.
You can define quantities in your DataService
subclass using pydase
's units
functionality. These quantities can be set and accessed like regular attributes, and pydase
will automatically handle the conversion between floats and quantities with units.
Here's an example:
from typing import Any
from pydase import DataService, Server
import pydase.units as u
class ServiceClass(DataService):
voltage = 1.0 * u.units.V
_current: u.Quantity = 1.0 * u.units.mA
@property
def current(self) -> u.Quantity:
return self._current
@current.setter
def current(self, value: Any) -> None:
self._current = value
if __name__ == "__main__":
service = ServiceClass()
# You can just set floats to the Quantity objects. The DataService __setattr__ will
# automatically convert this
service.voltage = 10.0
service.current = 1.5
Server(service).run()
In the frontend, quantities are rendered as floats, with the unit displayed as additional text. This allows you to maintain a clear and consistent representation of physical quantities across both the backend and frontend of your service.
Should you need to access the magnitude or the unit of a quantity, you can use the .m
attribute or the .u
attribute of the variable, respectively. For example, this could be necessary to set the periodicity of a task:
import asyncio
from pydase import DataService, Server
import pydase.units as u
class ServiceClass(DataService):
readout_wait_time = 1.0 * u.units.ms
async def read_sensor_data(self):
while True:
print("Reading out sensor ...")
await asyncio.sleep(self.readout_wait_time.to("s").m)
if __name__ == "__main__":
service = ServiceClass()
Server(service).run()
For more information about what you can do with the units, please consult the documentation of pint
.
Changing the Log Level
You can change the log level of loguru by either
-
(RECOMMENDED) setting the
ENVIRONMENT
environment variable to "production" or "development"ENVIRONMENT="production" python -m <module_using_pydase>
The production environment will only log messages above "INFO", the development environment (default) logs everything above "DEBUG".
-
calling the
pydase.utils.logging.setup_logging
function with the desired log level# <your_script.py> from pydase.utils.logging import setup_logging setup_logging("INFO")
Documentation
The full documentation provides more detailed information about pydase
, including advanced usage examples, API references, and tips for troubleshooting common issues. See the full documentation for more information.
Contributing
We welcome contributions! Please see contributing.md for details on how to contribute.
License
pydase
is licensed under the MIT License.
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