Federated evaluation¶
There are two main approaches to evaluating models in federated learning systems: centralized (or server-side) evaluation and federated (or client-side) evaluation.
Centralized Evaluation¶
Built-In Strategies¶
All built-in strategies support centralized evaluation by providing an evaluation function during initialization. An evaluation function is any function that can take the current global model parameters as input and return evaluation results:
from flwr.common import NDArrays, Scalar
from typing import Dict, Optional, Tuple
def get_evaluate_fn(model):
"""Return an evaluation function for server-side evaluation."""
# Load data and model here to avoid the overhead of doing it in `evaluate` itself
(x_train, y_train), _ = tf.keras.datasets.cifar10.load_data()
# Use the last 5k training examples as a validation set
x_val, y_val = x_train[45000:50000], y_train[45000:50000]
# The `evaluate` function will be called after every round
def evaluate(
server_round: int, parameters: NDArrays, config: Dict[str, Scalar]
) -> Optional[Tuple[float, Dict[str, Scalar]]]:
model.set_weights(parameters) # Update model with the latest parameters
loss, accuracy = model.evaluate(x_val, y_val)
return loss, {"accuracy": accuracy}
return evaluate
# Load and compile model for server-side parameter evaluation
model = tf.keras.applications.EfficientNetB0(
input_shape=(32, 32, 3), weights=None, classes=10
)
model.compile("adam", "sparse_categorical_crossentropy", metrics=["accuracy"])
# Create strategy
strategy = fl.server.strategy.FedAvg(
# ... other FedAvg arguments
evaluate_fn=get_evaluate_fn(model),
)
# Start Flower server for four rounds of federated learning
fl.server.start_server(server_address="[::]:8080", strategy=strategy)
Custom Strategies¶
The Strategy
abstraction provides a method called evaluate
that can directly be
used to evaluate the current global model parameters. The current server implementation
calls evaluate
after parameter aggregation and before federated evaluation (see next
paragraph).
Federated Evaluation¶
Implementing Federated Evaluation¶
Client-side evaluation happens in the Client.evaluate
method and can be configured
from the server side.
class CifarClient(fl.client.NumPyClient):
def __init__(self, model, x_train, y_train, x_test, y_test):
self.model = model
self.x_train, self.y_train = x_train, y_train
self.x_test, self.y_test = x_test, y_test
def get_parameters(self, config):
# ...
pass
def fit(self, parameters, config):
# ...
pass
def evaluate(self, parameters, config):
"""Evaluate parameters on the locally held test set."""
# Update local model with global parameters
self.model.set_weights(parameters)
# Get config values
steps: int = config["val_steps"]
# Evaluate global model parameters on the local test data and return results
loss, accuracy = self.model.evaluate(self.x_test, self.y_test, 32, steps=steps)
num_examples_test = len(self.x_test)
return loss, num_examples_test, {"accuracy": accuracy}
Configuring Federated Evaluation¶
Federated evaluation can be configured from the server side. Built-in strategies support the following arguments:
fraction_evaluate
: afloat
defining the fraction of clients that will be selected for evaluation. Iffraction_evaluate
is set to0.1
and100
clients are connected to the server, then10
will be randomly selected for evaluation. Iffraction_evaluate
is set to0.0
, federated evaluation will be disabled.min_evaluate_clients
: anint
: the minimum number of clients to be selected for evaluation. Iffraction_evaluate
is set to0.1
,min_evaluate_clients
is set to 20, and100
clients are connected to the server, then20
clients will be selected for evaluation.min_available_clients
: anint
that defines the minimum number of clients which need to be connected to the server before a round of federated evaluation can start. If fewer thanmin_available_clients
are connected to the server, the server will wait until more clients are connected before it continues to sample clients for evaluation.on_evaluate_config_fn
: a function that returns a configuration dictionary which will be sent to the selected clients. The function will be called during each round and provides a convenient way to customize client-side evaluation from the server side, for example, to configure the number of validation steps performed.
def evaluate_config(server_round: int):
"""Return evaluation configuration dict for each round.
Perform five local evaluation steps on each client (i.e., use five
batches) during rounds, one to three, then increase to ten local
evaluation steps.
"""
val_steps = 5 if server_round < 4 else 10
return {"val_steps": val_steps}
# Create strategy
strategy = fl.server.strategy.FedAvg(
# ... other FedAvg arguments
fraction_evaluate=0.2,
min_evaluate_clients=2,
min_available_clients=10,
on_evaluate_config_fn=evaluate_config,
)
# Start Flower server for four rounds of federated learning
fl.server.start_server(server_address="[::]:8080", strategy=strategy)
Evaluating Local Model Updates During Training¶
Model parameters can also be evaluated during training. Client.fit
can return
arbitrary evaluation results as a dictionary:
class CifarClient(fl.client.NumPyClient):
def __init__(self, model, x_train, y_train, x_test, y_test):
self.model = model
self.x_train, self.y_train = x_train, y_train
self.x_test, self.y_test = x_test, y_test
def get_parameters(self, config):
# ...
pass
def fit(self, parameters, config):
"""Train parameters on the locally held training set."""
# Update local model parameters
self.model.set_weights(parameters)
# Train the model using hyperparameters from config
history = self.model.fit(
self.x_train, self.y_train, batch_size=32, epochs=2, validation_split=0.1
)
# Return updated model parameters and validation results
parameters_prime = self.model.get_weights()
num_examples_train = len(self.x_train)
results = {
"loss": history.history["loss"][0],
"accuracy": history.history["accuracy"][0],
"val_loss": history.history["val_loss"][0],
"val_accuracy": history.history["val_accuracy"][0],
}
return parameters_prime, num_examples_train, results
def evaluate(self, parameters, config):
# ...
pass
Full Code Example¶
For a full code example that uses both centralized and federated evaluation, see the Advanced TensorFlow Example (the same approach can be applied to workloads implemented in any other framework): https://github.com/adap/flower/tree/main/examples/advanced-tensorflow