OpenFeature is an open specification that provides a vendor-agnostic, community-driven API for feature flagging that works with your favorite feature flag management tool.
🚀 Quick start
Requirements
Python 3.8+
Install
Pip install
pip install openfeature-sdk==0.7.4
requirements.txt
openfeature-sdk==0.7.4
pip install -r requirements.txt
Usage
from openfeature import api
from openfeature.provider.in_memory_provider import InMemoryFlag, InMemoryProvider
# flags defined in memory
my_flags = {
"v2_enabled": InMemoryFlag("on", {"on": True, "off": False})
}
# configure a provider
api.set_provider(InMemoryProvider(my_flags))
# create a client
client = api.get_client()
# get a bool flag value
flag_value = client.get_boolean_value("v2_enabled", False)
print("Value: " + str(flag_value))
Extend OpenFeature with custom providers and hooks.
Implemented: ✅ | In-progress: ⚠️ | Not implemented yet: ❌
Providers
Providers are an abstraction between a flag management system and the OpenFeature SDK.
Look here for a complete list of available providers.
If the provider you're looking for hasn't been created yet, see the develop a provider section to learn how to build it yourself.
Once you've added a provider as a dependency, it can be registered with OpenFeature like this:
from openfeature import api
from openfeature.provider.no_op_provider import NoOpProvider
api.set_provider(NoOpProvider())
open_feature_client = api.get_client()
In some situations, it may be beneficial to register multiple providers in the same application.
This is possible using domains, which is covered in more detail below.
Targeting
Sometimes, the value of a flag must consider some dynamic criteria about the application or user, such as the user's location, IP, email address, or the server's location.
In OpenFeature, we refer to this as targeting.
If the flag management system you're using supports targeting, you can provide the input data using the evaluation context.
from openfeature.api import (
get_client,
get_provider,
set_provider,
get_evaluation_context,
set_evaluation_context,
)
global_context = EvaluationContext(
targeting_key="targeting_key1", attributes={"application": "value1"}
)
request_context = EvaluationContext(
targeting_key="targeting_key2", attributes={"email": request.form['email']}
)
## set global context
set_evaluation_context(global_context)
# merge second context
client = get_client(name="No-op Provider")
client.get_string_value("email", "fallback", request_context)
Hooks
Hooks allow for custom logic to be added at well-defined points of the flag evaluation life-cycle.
Look here for a complete list of available hooks.
If the hook you're looking for hasn't been created yet, see the develop a hook section to learn how to build it yourself.
Once you've added a hook as a dependency, it can be registered at the global, client, or flag invocation level.
from openfeature.api import add_hooks
from openfeature.flag_evaluation import FlagEvaluationOptions
# set global hooks at the API-level
add_hooks([MyHook()])
# or configure them in the client
client = OpenFeatureClient()
client.add_hooks([MyHook()])
# or at the invocation-level
options = FlagEvaluationOptions(hooks=[MyHook()])
client.get_boolean_flag("my-flag", False, flag_evaluation_options=options)
Logging
The OpenFeature SDK logs to the openfeature logger using the logging package from the Python Standard Library.
Domains
Clients can be assigned to a domain.
A domain is a logical identifier which can be used to associate clients with a particular provider.
If a domain has no associated provider, the global provider is used.
from openfeature import api
# Registering the default provider
api.set_provider(MyProvider());
# Registering a provider to a domain
api.set_provider(MyProvider(), "my-domain");
# A client bound to the default provider
default_client = api.get_client();
# A client bound to the MyProvider provider
domain_scoped_client = api.get_client("my-domain");
Domains can be defined on a provider during registration.
For more details, please refer to the providers section.
Eventing
Events allow you to react to state changes in the provider or underlying flag management system, such as flag definition changes, provider readiness, or error conditions. Initialization events (PROVIDER_READY on success, PROVIDER_ERROR on failure) are dispatched for every provider. Some providers support additional events, such as PROVIDER_CONFIGURATION_CHANGED.
Please refer to the documentation of the provider you're using to see what events are supported.
from openfeature import api
from openfeature.provider import ProviderEvent
defon_provider_ready(event_details: EventDetails):
print(f"Provider {event_details.provider_name} is ready")
api.add_handler(ProviderEvent.PROVIDER_READY, on_provider_ready)
client = api.get_client()
defon_provider_ready(event_details: EventDetails):
print(f"Provider {event_details.provider_name} is ready")
client.add_handler(ProviderEvent.PROVIDER_READY, on_provider_ready)
Transaction Context Propagation
Transaction context is a container for transaction-specific evaluation context (e.g. user id, user agent, IP).
Transaction context can be set where specific data is available (e.g. an auth service or request handler) and by using the transaction context propagator it will automatically be applied to all flag evaluations within a transaction (e.g. a request or thread).
You can implement a different transaction context propagator by implementing the TransactionContextPropagator class exported by the OpenFeature SDK.
In most cases you can use ContextVarsTransactionContextPropagator as it works for threads and asyncio using Context Variables.
The following example shows a multithreaded Flask application using transaction context propagation to propagate the request ip and user id into request scoped transaction context.
from flask import Flask, request
from openfeature import api
from openfeature.evaluation_context import EvaluationContext
from openfeature.transaction_context import ContextVarsTransactionContextPropagator
# Initialize the Flask app
app = Flask(__name__)
# Set the transaction context propagator
api.set_transaction_context_propagator(ContextVarsTransactionContextPropagator())
# Middleware to set the transaction context# You can call api.set_transaction_context anywhere you have information,# you want to have available in the code-paths below the current one.@app.before_requestdefset_request_transaction_context():
ip = request.headers.get("X-Forwarded-For", request.remote_addr)
user_id = request.headers.get("User-Id") # Assuming we're getting the user ID from a header
evaluation_context = EvaluationContext(targeting_key=user_id, attributes={"ipAddress": ip})
api.set_transaction_context(evaluation_context)
defcreate_response() -> str:
# This method can be anywhere in our code.# The feature flag evaluation will automatically contain the transaction context merged with other context
new_response = api.get_client().get_string_value("response-message", "Hello User!")
returnf"Message from server: {new_response}"# Example route where we use the transaction context@app.route('/greeting')defsome_endpoint():
return create_response()
This also works for asyncio based implementations e.g. FastApi as seen in the following example:
from fastapi import FastAPI, Request
from openfeature import api
from openfeature.evaluation_context import EvaluationContext
from openfeature.transaction_context import ContextVarsTransactionContextPropagator
# Initialize the FastAPI app
app = FastAPI()
# Set the transaction context propagator
api.set_transaction_context_propagator(ContextVarsTransactionContextPropagator())
# Middleware to set the transaction context@app.middleware("http")asyncdefset_request_transaction_context(request: Request, call_next):
ip = request.headers.get("X-Forwarded-For", request.client.host)
user_id = request.headers.get("User-Id") # Assuming we're getting the user ID from a header
evaluation_context = EvaluationContext(targeting_key=user_id, attributes={"ipAddress": ip})
api.set_transaction_context(evaluation_context)
response = await call_next(request)
return response
defcreate_response() -> str:
# This method can be located anywhere in our code.# The feature flag evaluation will automatically include the transaction context merged with other context.
new_response = api.get_client().get_string_value("response-message", "Hello User!")
returnf"Message from server: {new_response}"# Example route where we use the transaction context@app.get('/greeting')asyncdefsome_endpoint():
return create_response()
Shutdown
The OpenFeature API provides a shutdown function to perform a cleanup of all registered providers. This should only be called when your application is in the process of shutting down.
from openfeature import api
api.shutdown()
Extending
Develop a provider
To develop a provider, you need to create a new project and include the OpenFeature SDK as a dependency.
This can be a new repository or included in the existing contrib repository available under the OpenFeature organization.
You’ll then need to write the provider by implementing the AbstractProvider class exported by the OpenFeature SDK.
Built a new provider? Let us know so we can add it to the docs!
Develop a hook
To develop a hook, you need to create a new project and include the OpenFeature SDK as a dependency.
This can be a new repository or included in the existing contrib repository available under the OpenFeature organization.
Implement your own hook by creating a hook that inherits from the Hook class.
Any of the evaluation life-cycle stages (before/after/error/finally_after) can be override to add the desired business logic.
from openfeature.hook import Hook
classMyHook(Hook):
defafter(self, hook_context: HookContext, details: FlagEvaluationDetails, hints: dict):
print("This runs after the flag has been evaluated")
Built a new hook? Let us know so we can add it to the docs!
We found that openfeature-sdk demonstrated a healthy version release cadence and project activity because the last version was released less than a year ago.It has 1 open source maintainer collaborating on the project.
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