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Posted on • Originally published at developer-service.blog

How to Quickly Build APIs in Python

APIs are the backbone of most applications that rely on data exchange or external integrations.

Learning to build APIs in Python can open up many opportunities to connect your app with other systems and make a versatile backend.

Here, I’ll walk you through the basics of APIs, creating REST APIs, and building them with Flask and FastAPI—two popular Python frameworks.


1. Introduction to APIs

In today’s digital world, APIs are everywhere.

They allow different systems and applications to talk to each other, sharing data and functionalities seamlessly.

For example, when you use an app to check the weather, it's actually calling an API that returns the weather data.

APIs make life easier by acting as intermediaries that process requests and return data in a standardized way.

It’s also worth noting that APIs don’t only serve client applications (like websites or mobile apps).

APIs can be used between backend systems or microservices within the same infrastructure to manage data more efficiently.


2. REST APIs

REST (Representational State Transfer) is one of the most popular ways to create APIs due to its simplicity and compatibility with HTTP.

RESTful APIs are structured to allow standard HTTP methods (like GET, POST, PUT, DELETE) to manipulate resources.

They’re often used to manage CRUD (Create, Read, Update, and Delete) operations, where each request method performs an operation on the resource data.

If you're building a web service, REST is likely the most approachable and widely supported format to start with.

REST APIs are also stateless, which means each request operates independently, allowing REST APIs to scale more easily.


3. Building an API with Flask

Flask is my go-to for small or medium-sized projects, as it’s lightweight and easy to get up and running.

Flask lets you control nearly every aspect of your API, but it also requires a bit more work on data validation and error handling.

This flexibility, though, is ideal for those who want more control over how each part of the API functions.

Example of Creating a Flask API

Here’s how a task management API can look in Flask.

First, make sure to install flask with pip:

pip install flask
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This example shows how you can quickly set up endpoints for getting and creating tasks, as well as updating and deleting.

from flask import Flask, jsonify, request

app = Flask(__name__)

tasks = [
    {"id": 1, "task": "Learn Flask", "done": False},
    {"id": 2, "task": "Build API", "done": False}
]

@app.route('/tasks', methods=['GET'])
def get_tasks():
    return jsonify({"tasks": tasks})

@app.route('/tasks', methods=['POST'])
def create_task():
    new_task = {
        "id": len(tasks) + 1,
        "task": request.json["task"],
        "done": False
    }
    tasks.append(new_task)
    return jsonify(new_task), 201

@app.route('/tasks/<int:task_id>', methods=['GET'])
def get_task(task_id):
    task = next((task for task in tasks if task["id"] == task_id), None)
    if task:
        return jsonify(task)
    return jsonify({"message": "Task not found"}), 404

@app.route('/tasks/<int:task_id>', methods=['PUT'])
def update_task(task_id):
    task = next((task for task in tasks if task["id"] == task_id), None)
    if task:
        task.update(request.json)
        return jsonify(task)
    return jsonify({"message": "Task not found"}), 404

@app.route('/tasks/<int:task_id>', methods=['DELETE'])
def delete_task(task_id):
    task = next((task for task in tasks if task["id"] == task_id), None)
    if task:
        tasks.remove(task)
        return jsonify({"message": "Task deleted"})
    return jsonify({"message": "Task not found"}), 404

if __name__ == '__main__':
    app.run(debug=True)

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This Python code sets up a REST API using Flask to manage a list of tasks, allowing clients to create, retrieve, update, and delete tasks.

The tasks are stored in a list where each task is a dictionary with an id, task, and done status.

The /tasks endpoint supports GET requests to return the full list of tasks and POST requests to add new tasks, automatically assigning each task a unique ID.

Additional endpoints, /tasks/<int:task_id>, allow users to interact with individual tasks: GET retrieves a specific task by ID, PUT updates it, and DELETE removes it from the list.

If a task with the specified ID is not found, these endpoints return a 404 error with an appropriate message.

The API runs in debug mode, making it ideal for development and testing purposes.

Just be aware that for larger projects, you might need to add more structured routing and validation mechanisms.


4. Building an API with FastAPI

FastAPI is an excellent choice for performance-sensitive applications or projects that require a bit more structure and type safety.

FastAPI is designed to be faster by default (thanks to its asynchronous capabilities) and offers robust data validation out-of-the-box using Pydantic.

I’ve found FastAPI very intuitive and easy to work with, especially for projects where I need async capabilities and want built-in validation without third-party packages.

Plus, the automatic documentation (via Swagger UI) makes it extremely convenient.

Example of Creating a FastAPI API

Here’s how the task management API could look in FastAPI.

Don't forget to first install fastapi and uvicorn with pip:

pip install fastapi uvicorn
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Then you can create the API:

from fastapi import FastAPI, HTTPException
from pydantic import BaseModel
from typing import List

app = FastAPI()

class Task(BaseModel):
    id: int
    task: str
    done: bool = False

tasks: List[Task] = [
    Task(id=1, task="Learn FastAPI", done=False),
    Task(id=2, task="Build API", done=False)
]

@app.get("/tasks", response_model=List[Task])
def get_tasks():
    return tasks

@app.post("/tasks", response_model=Task)
def create_task(task: Task):
    tasks.append(task)
    return task

@app.get("/tasks/{task_id}", response_model=Task)
def get_task(task_id: int):
    task = next((task for task in tasks if task.id == task_id), None)
    if task:
        return task
    raise HTTPException(status_code=404, detail="Task not found")

@app.put("/tasks/{task_id}", response_model=Task)
def update_task(task_id: int, task: Task):
    for t in tasks:
        if t.id == task_id:
            t.task = task.task
            t.done = task.done
            return t
    raise HTTPException(status_code=404, detail="Task not found")

@app.delete("/tasks/{task_id}")
def delete_task(task_id: int):
    for t in tasks:
        if t.id == task_id:
            tasks.remove(t)
            return {"message": "Task deleted"}
    raise HTTPException(status_code=404, detail="Task not found")

if __name__ == "__main__":
    import uvicorn

    uvicorn.run(app, host="127.0.0.1", port=8000)

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This Python code creates a task management API using FastAPI, leveraging Pydantic models for data validation and type enforcement.

It defines a Task model with an id, task, and done status, and initializes a list of tasks.

The API includes endpoints to perform CRUD operations on tasks: the /tasks endpoint allows GET requests to retrieve the task list and POST requests to add a new task, automatically validating incoming data.

The /tasks/{task_id} endpoint allows specific task retrieval with GET, updating with PUT, and deletion with DELETE, returning a 404 error if a task with the specified id is not found.

FastAPI's asynchronous capabilities and integrated documentation make this API efficient and easy to test, ideal for rapid development.


5. Testing APIs

Testing is critical, especially when creating an API that other applications will consume.

Flask and FastAPI provide excellent support for unit testing, making it easy to verify each endpoint’s behavior.

To make testing easier, I’d recommend using pytest for general test structure, as it’s compatible with both Flask and FastAPI.

For FastAPI specifically, TestClient is a helpful tool to mock HTTP requests and check responses.

You will need to install httpx with pip:

pip install httpx
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Here’s an example for testing a FastAPI endpoint:

from fastapi.testclient import TestClient
from main import app

client = TestClient(app)

def test_get_tasks():
    response = client.get("/tasks")
    assert response.status_code == 200
    assert "tasks" in response.json()

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With both frameworks, testing is straightforward and allows you to verify that your API behaves as expected, especially as it evolves.


6. Comparison Between Flask and FastAPI

Let's see a comparison between Flask and FastAPI

Comparison between FastAPI and Flask

If you’re working on a quick prototype or a smaller project, Flask’s simplicity might be all you need.

For projects that require high concurrency, data validation, or auto-documentation, FastAPI provides a more powerful, feature-rich environment.


7. Conclusion

Both Flask and FastAPI have strengths that make them suited to different types of projects.

If you’re new to Python web development, starting with Flask can help you understand the basics before moving to something more advanced.

FastAPI, on the other hand, is an ideal choice if you’re looking for modern, high-performance API development with built-in validation and documentation.

No matter which you choose, Python offers a robust ecosystem for API development.

Both frameworks will allow you to create APIs that can power diverse applications, from simple websites to complex microservices.

The key is to experiment, understand each framework's strengths, and pick the right tool for your needs.

Top comments (1)

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philip_zhang_854092d88473 profile image
Philip

Thanks for always providing such great information on RESTful APIs! I’ve found EchoAPI to be a great addition to my toolkit, making it easy to simulate different API states and test without backend dependencies.