Event Sourcing with gRPC
This is an extension for the Python eventsourcing library.
This package provides a gRPC server class that runs event-sourced applications
in a gRPC server. A gRPC client class can be used to interact with the application
server. Application command and query methods can be called, and
notifications selected, remotely using an application proxy object
provided by the client.
This package also provides a system runner class, with the same interface as the Runner
classes in the core eventsourcing library. It can run a system of event-sourced
applications as a set of gRPC servers. Leader and follower connections, for prompting
and pulling event notifications, are implemented with gRPC clients.
This package provides console commands that can be used to start servers and run systems
from a command line interface.
This package also provides an example of running an event-sourced application in
gRPC server in a Docker container.
This package also provides an example of running a system of applications
in gRPC servers in Docker containers with docker-compose.
This package also provides an example of running a system of applications
in gRPC servers in Docker containers with Kubernetes, with clients and
servers authenticated with SSL/TLS PKI certificates.
Installation
Use pip to install the stable distribution
from the Python Package Index.
$ pip install eventsourcing_grpc
It is recommended to install Python packages into a Python virtual environment.
gRPC clients and servers
The GrpcApplicationServer
class can be used to run an event-sourced
application as a gRPC server, and the GrpcApplicationClient
class can
be used to connect to a server.
Define an event-sourced application.
from eventsourcing_grpc.example import Orders
Configure with environment variables.
import os
os.environ["ORDERS_GRPC_SERVER_ADDRESS"] = "localhost:50051"
Application persistence can be configured in the usual way (see core library docs).
Use the start_server()
function to create and start a gRPC application server.
from eventsourcing_grpc.application_server import start_server
server = start_server(Orders)
Use the connect()
function to create a gRPC client and connect to the server.
from eventsourcing_grpc.application_client import connect
client = connect(Orders, max_attempts=10)
Use the application proxy to call command and query methods on the application server.
order_id = client.app.create_new_order()
order = client.app.get_order(order_id)
assert order["id"] == order_id
assert order["is_reserved"] == False
assert order["is_paid"] == False
Use the application proxy to select event notifications.
notifications = client.app.notification_log.select(start=1, limit=10)
assert len(notifications) == 1
assert notifications[0].id == 1
assert notifications[0].originator_id == order_id
assert notifications[0].originator_version == 1
assert notifications[0].topic == "eventsourcing_grpc.example:Order.Created"
Close client and stop server.
client.close()
server.stop(wait=True)
gRPC runner
The GrpcRunner
class can be used to run a system of event-sourced applications
as an inter-connected set of gRPC servers.
from eventsourcing_grpc.runner import GrpcRunner
Define a system of event-sourced applications.
from eventsourcing_grpc.example import system
Configure with environment variables.
import os
os.environ["ORDERS_GRPC_SERVER_ADDRESS"] = "localhost:50051"
os.environ["RESERVATIONS_GRPC_SERVER_ADDRESS"] = "localhost:50052"
os.environ["PAYMENTS_GRPC_SERVER_ADDRESS"] = "localhost:50053"
Create and start a gRPC system runner (starts servers and connects clients).
runner = GrpcRunner(system)
runner.start(with_subprocesses=True)
Get an application proxy from the runner.
app = runner.get(Orders)
Call command and query methods on application proxy.
order1_id = app.create_new_order()
from time import sleep
for _ in range(100):
sleep(0.1)
if app.is_order_paid(order1_id):
break
elif runner.has_errored.is_set():
raise AssertionError("Runner error")
else:
raise AssertionError("Timeout waiting for order to be paid")
Get application's event notifications.
notifications = app.notification_log.select(start=1, limit=10)
assert len(notifications) == 3
assert notifications[0].id == 1
assert notifications[0].originator_id == order1_id
assert notifications[0].originator_version == 1
assert notifications[0].topic == "eventsourcing_grpc.example:Order.Created"
assert notifications[1].id == 2
assert notifications[1].originator_id == order1_id
assert notifications[1].originator_version == 2
assert notifications[1].topic == "eventsourcing_grpc.example:Order.Reserved"
assert notifications[2].id == 3
assert notifications[2].originator_id == order1_id
assert notifications[2].originator_version == 3
assert notifications[2].topic == "eventsourcing_grpc.example:Order.Paid"
Stop runner (closes clients and stops servers).
runner.stop()
Start server from command line
The console command eventsourcing_grpc_server
can be used to start
a gRPC application server. The application topic can be given as a
command line argument.
$ export ORDERS_GRPC_SERVER_ADDRESS=localhost:50051
$ eventsourcing_grpc_server eventsourcing_grpc.example:Orders
A system of interconnected application servers can be started in this way,
after setting SYSTEM_TOPIC
in the environment.
$ export SYSTEM_TOPIC=eventsourcing_grpc.example:system
$ export ORDERS_GRPC_SERVER_ADDRESS=localhost:50051
$ export RESERVATIONS_GRPC_SERVER_ADDRESS=localhost:50052
$ export PAYMENTS_GRPC_SERVER_ADDRESS=localhost:50053
$ eventsourcing_grpc_server eventsourcing_grpc.example:Orders &
$ eventsourcing_grpc_server eventsourcing_grpc.example:Reservations &
$ eventsourcing_grpc_server eventsourcing_grpc.example:Payments &
In the example above, the servers are run as background processes.
Start runner from command line
The console command eventsourcing_grpc_runner
can be used to run a system
of event-sourced applications. Only the system topic must be configured.
The system topic can be given as a command line argument.
$ eventsourcing_grpc_runner eventsourcing_grpc.example:system
Alternatively, the system topic can be set using the SYSTEM_TOPIC
environment variable.
$ export SYSTEM_TOPIC=eventsourcing_grpc.example:system
$ eventsourcing_grpc_runner
The server addresses will be automatically configured, unless they are set as
environment variables.
Docker container
A Docker file can be defined to run the eventsourcing_grpc_server
command
mentioned above, after installing an event-sourced system and the eventsourcing_grpc
package.
FROM python:3.10
WORKDIR /app
# Install package(s).
RUN pip install eventsourcing_grpc
# Run application server.
ENV PYTHONUNBUFFERED = 1
CMD ["eventsourcing_grpc_server"]
A container image can then be built with Docker.
$ docker build -t eventsourcing-grpc -f Dockerfile .
Docker Compose
A system of gRPC application servers can be run with Docker Compose.
The following Docker Compose file assumes SSL/TLS PKI certificates
have been generated in a local ./ssl
folder.
version: '2'
services:
orders:
image: "eventsourcing-grpc:v1"
environment:
APPLICATION_TOPIC: "eventsourcing_grpc.example:Orders"
SYSTEM_TOPIC: "eventsourcing_grpc.example:system"
ORDERS_GRPC_SERVER_ADDRESS: "orders:50051"
RESERVATIONS_GRPC_SERVER_ADDRESS: "reservations:50052"
PAYMENTS_GRPC_SERVER_ADDRESS: "payments:50053"
MAX_PULL_INTERVAL: "10"
GRPC_SSL_PRIVATE_KEY_PATH: /app/ssl/orders.key
GRPC_SSL_CERTIFICATE_PATH: /app/ssl/orders.crt
GRPC_SSL_ROOT_CERTIFICATE_PATH: /app/ssl/root.crt
volumes:
- ./ssl/orders:/app/ssl
ports:
- "50051:50051"
reservations:
image: "eventsourcing-grpc:v1"
environment:
APPLICATION_TOPIC: "eventsourcing_grpc.example:Reservations"
SYSTEM_TOPIC: "eventsourcing_grpc.example:system"
ORDERS_GRPC_SERVER_ADDRESS: "orders:50051"
RESERVATIONS_GRPC_SERVER_ADDRESS: "reservations:50052"
PAYMENTS_GRPC_SERVER_ADDRESS: "payments:50053"
MAX_PULL_INTERVAL: "10"
GRPC_SSL_PRIVATE_KEY_PATH: /app/ssl/reservations.key
GRPC_SSL_CERTIFICATE_PATH: /app/ssl/reservations.crt
GRPC_SSL_ROOT_CERTIFICATE_PATH: /app/ssl/root.crt
volumes:
- ./ssl/reservations:/app/ssl
ports:
- "50052:50052"
payments:
image: "eventsourcing-grpc:v1"
environment:
APPLICATION_TOPIC: "eventsourcing_grpc.example:Payments"
SYSTEM_TOPIC: "eventsourcing_grpc.example:system"
ORDERS_GRPC_SERVER_ADDRESS: "orders:50051"
RESERVATIONS_GRPC_SERVER_ADDRESS: "reservations:50052"
PAYMENTS_GRPC_SERVER_ADDRESS: "payments:50053"
MAX_PULL_INTERVAL: "10"
GRPC_SSL_PRIVATE_KEY_PATH: /app/ssl/payments.key
GRPC_SSL_CERTIFICATE_PATH: /app/ssl/payments.crt
GRPC_SSL_ROOT_CERTIFICATE_PATH: /app/ssl/root.crt
volumes:
- ./ssl/payments:/app/ssl
ports:
- "50053:50053"
The containers can then be started.
$ docker-compose up -d
Kubernetes
A system of gRPC application servers can be run with Kubernetes.
Create Kubernetes Secrets from the SSL/TLS PKI certificates.
$ kubectl create secret generic root-ssl-secret \
--from-file=root.crt=ssl/root/root.crt
$ kubectl create secret tls orders-ssl-secret \
--key ./ssl/orders/orders.key \
--cert ./ssl/orders/orders.crt
$ kubectl create secret tls reservations-ssl-secret \
--key ./ssl/reservations/reservations.key \
--cert ./ssl/reservations/reservations.crt
$ kubectl create secret tls payments-ssl-secret \
--key ./ssl/payments/payments.key \
--cert ./ssl/payments/payments.crt
Create a Kubernetes Deployment for each application.
apiVersion: apps/v1
kind: Deployment
metadata:
name: orders
labels:
system: orders
spec:
selector:
matchLabels:
app: orders
replicas: 1
template:
metadata:
labels:
app: orders
spec:
volumes:
- name: ssl-secret-volume
secret:
secretName: orders-ssl-secret
- name: root-ssl-secret-volume
secret:
secretName: root-ssl-secret
containers:
- name: orders
image: "eventsourcing-grpc:latest"
imagePullPolicy: Never
ports:
- containerPort: 50051
volumeMounts:
- mountPath: /app/ssl
name: ssl-secret-volume
- mountPath: /app/root-ssl
name: root-ssl-secret-volume
env:
- name: APPLICATION_TOPIC
value: "eventsourcing_grpc.example:Orders"
- name: SYSTEM_TOPIC
value: "eventsourcing_grpc.example:system"
- name: ORDERS_GRPC_SERVER_ADDRESS
value: "0.0.0.0:50051"
- name: RESERVATIONS_GRPC_SERVER_ADDRESS
value: "reservations:50052"
- name: PAYMENTS_GRPC_SERVER_ADDRESS
value: "payments:50053"
- name: GRPC_SSL_PRIVATE_KEY_PATH
value: /app/ssl/tls.key
- name: GRPC_SSL_CERTIFICATE_PATH
value: /app/ssl/tls.crt
- name: GRPC_SSL_ROOT_CERTIFICATE_PATH
value: /app/root-ssl/root.crt
Create a Kubernetes Service for each Deployment.
apiVersion: v1
kind: Service
metadata:
name: orders
labels:
system: orders
spec:
selector:
app: orders
type: LoadBalancer
ports:
- port: 50051
targetPort: 50051
protocol: TCP
The above configuration will run each application on a separate Pod. Alternatively,
you can run all the applications in the same Pod, by defining a multi-container
Deployment.
Please refer to the project repo (and its GitHub actions workflow and Makefile)
to see a fully working example of running a system of applications with minikube.
Developers
After cloning the eventsourcing-grpc repository, set up a virtual
environment and install dependencies by running the following command in the
root folder.
$ make install
The make install
command uses the build tool Poetry to create a dedicated
Python virtual environment for this project, and installs popular development
dependencies such as Black, isort and pytest.
Add tests in ./tests
. Add code in ./eventsourcing_grpc
.
Generate SSL/TLS certificates and private keys for testing.
$ make ssl
Run tests.
$ make test
Check the formatting of the code.
$ make lint
Reformat the code.
$ make fmt
Add dependencies in pyproject.toml
and then update installed packages.
$ make update-packages
If you edit the .proto files, regenerate the project's protos package.
$ make grpc-stubs