SQL (Relational) Databases with Peewee¶
Warning
If you are just starting, the tutorial SQL (Relational) Databases that uses SQLAlchemy should be enough.
Feel free to skip this.
If you are starting a project from scratch, you are probably better off with SQLAlchemy ORM (SQL (Relational) Databases), or any other async ORM.
If you already have a code base that uses Peewee ORM, you can check here how to use it with FastAPI.
Python 3.7+ required
You will need Python 3.7 or above to safely use Peewee with FastAPI.
Peewee for async¶
Peewee was not designed for async frameworks, or with them in mind.
Peewee has some heavy assumptions about its defaults and about how it should be used.
If you are developing an application with an older non-async framework, and can work with all its defaults, it can be a great tool.
But if you need to change some of the defaults, support more than one predefined database, work with an async framework (like FastAPI), etc, you will need to add quite some complex extra code to override those defaults.
Nevertheless, it's possible to do it, and here you'll see exactly what code you have to add to be able to use Peewee with FastAPI.
Technical Details
You can read more about Peewee's stand about async in Python in the docs, an issue, a PR.
The same app¶
We are going to create the same application as in the SQLAlchemy tutorial (SQL (Relational) Databases).
Most of the code is actually the same.
So, we are going to focus only on the differences.
File structure¶
Let's say you have a directory named my_super_project
that contains a sub-directory called sql_app
with a structure like this:
.
└── sql_app
├── __init__.py
├── crud.py
├── database.py
├── main.py
└── schemas.py
This is almost the same structure as we had for the SQLAlchemy tutorial.
Now let's see what each file/module does.
Create the Peewee parts¶
Let's refer to the file sql_app/database.py
.
The standard Peewee code¶
Let's first check all the normal Peewee code, create a Peewee database:
from contextvars import ContextVar
import peewee
DATABASE_NAME = "test.db"
db_state_default = {"closed": None, "conn": None, "ctx": None, "transactions": None}
db_state = ContextVar("db_state", default=db_state_default.copy())
class PeeweeConnectionState(peewee._ConnectionState):
def __init__(self, **kwargs):
super().__setattr__("_state", db_state)
super().__init__(**kwargs)
def __setattr__(self, name, value):
self._state.get()[name] = value
def __getattr__(self, name):
return self._state.get()[name]
db = peewee.SqliteDatabase(DATABASE_NAME, check_same_thread=False)
db._state = PeeweeConnectionState()
Tip
Have in mind that if you wanted to use a different database, like PostgreSQL, you couldn't just change the string. You would need to use a different Peewee database class.
Note¶
The argument:
check_same_thread=False
is equivalent to the one in the SQLAlchemy tutorial:
connect_args={"check_same_thread": False}
...it is needed only for SQLite
.
Technical Details
Exactly the same technical details as in SQL (Relational) Databases apply.
Make Peewee async-compatible PeeweeConnectionState
¶
The main issue with Peewee and FastAPI is that Peewee relies heavily on Python's threading.local
, and it doesn't have a direct way to override it or let you handle connections/sessions directly (as is done in the SQLAlchemy tutorial).
And threading.local
is not compatible with the new async features of modern Python.
Technical Details
threading.local
is used to have a "magic" variable that has a different value for each thread.
This was useful in older frameworks designed to have one single thread per request, no more, no less.
Using this, each request would have its own database connection/session, which is the actual final goal.
But FastAPI, using the new async features, could handle more than one request on the same thread. And at the same time, for a single request, it could run multiple things in different threads (in a threadpool), depending on if you use async def
or normal def
. This is what gives all the performance improvements to FastAPI.
But Python 3.7 and above provide a more advanced alternative to threading.local
, that can also be used in the places where threading.local
would be used, but is compatible with the new async features.
We are going to use that. It's called contextvars
.
We are going to override the internal parts of Peewee that use threading.local
and replace them with contextvars
, with the corresponding updates.
This might seem a bit complex (and it actually is), you don't really need to completely understand how it works to use it.
We will create a PeeweeConnectionState
:
from contextvars import ContextVar
import peewee
DATABASE_NAME = "test.db"
db_state_default = {"closed": None, "conn": None, "ctx": None, "transactions": None}
db_state = ContextVar("db_state", default=db_state_default.copy())
class PeeweeConnectionState(peewee._ConnectionState):
def __init__(self, **kwargs):
super().__setattr__("_state", db_state)
super().__init__(**kwargs)
def __setattr__(self, name, value):
self._state.get()[name] = value
def __getattr__(self, name):
return self._state.get()[name]
db = peewee.SqliteDatabase(DATABASE_NAME, check_same_thread=False)
db._state = PeeweeConnectionState()
This class inherits from a special internal class used by Peewee.
It has all the logic to make Peewee use contextvars
instead of threading.local
.
contextvars
works a bit differently than threading.local
. But the rest of Peewee's internal code assumes that this class works with threading.local
.
So, we need to do some extra tricks to make it work as if it was just using threading.local
. The __init__
, __setattr__
, and __getattr__
implement all the required tricks for this to be used by Peewee without knowing that it is now compatible with FastAPI.
Tip
This will just make Peewee behave correctly when used with FastAPI. Not randomly opening or closing connections that are being used, creating errors, etc.
But it doesn't give Peewee async super-powers. You should still use normal def
functions and not async def
.
Use the custom PeeweeConnectionState
class¶
Now, overwrite the ._state
internal attribute in the Peewee database db
object using the new PeeweeConnectionState
:
from contextvars import ContextVar
import peewee
DATABASE_NAME = "test.db"
db_state_default = {"closed": None, "conn": None, "ctx": None, "transactions": None}
db_state = ContextVar("db_state", default=db_state_default.copy())
class PeeweeConnectionState(peewee._ConnectionState):
def __init__(self, **kwargs):
super().__setattr__("_state", db_state)
super().__init__(**kwargs)
def __setattr__(self, name, value):
self._state.get()[name] = value
def __getattr__(self, name):
return self._state.get()[name]
db = peewee.SqliteDatabase(DATABASE_NAME, check_same_thread=False)
db._state = PeeweeConnectionState()
Tip
Make sure you overwrite db._state
after creating db
.
Tip
You would do the same for any other Peewee database, including PostgresqlDatabase
, MySQLDatabase
, etc.
Create the database models¶
Let's now see the file sql_app/models.py
.
Create Peewee models for our data¶
Now create the Peewee models (classes) for User
and Item
.
This is the same you would do if you followed the Peewee tutorial and updated the models to have the same data as in the SQLAlchemy tutorial.
Tip
Peewee also uses the term "model" to refer to these classes and instances that interact with the database.
But Pydantic also uses the term "model" to refer to something different, the data validation, conversion, and documentation classes and instances.
Import db
from database
(the file database.py
from above) and use it here.
import peewee
from .database import db
class User(peewee.Model):
email = peewee.CharField(unique=True, index=True)
hashed_password = peewee.CharField()
is_active = peewee.BooleanField(default=True)
class Meta:
database = db
class Item(peewee.Model):
title = peewee.CharField(index=True)
description = peewee.CharField(index=True)
owner = peewee.ForeignKeyField(User, backref="items")
class Meta:
database = db
Tip
Peewee creates several magic attributes.
It will automatically add an id
attribute as an integer to be the primary key.
It will chose the name of the tables based on the class names.
For the Item
, it will create an attribute owner_id
with the integer ID of the User
. But we don't declare it anywhere.
Create the Pydantic models¶
Now let's check the file sql_app/schemas.py
.
Tip
To avoid confusion between the Peewee models and the Pydantic models, we will have the file models.py
with the Peewee models, and the file schemas.py
with the Pydantic models.
These Pydantic models define more or less a "schema" (a valid data shape).
So this will help us avoiding confusion while using both.
Create the Pydantic models / schemas¶
Create all the same Pydantic models as in the SQLAlchemy tutorial:
from typing import Any, List, Union
import peewee
from pydantic import BaseModel
from pydantic.utils import GetterDict
class PeeweeGetterDict(GetterDict):
def get(self, key: Any, default: Any = None):
res = getattr(self._obj, key, default)
if isinstance(res, peewee.ModelSelect):
return list(res)
return res
class ItemBase(BaseModel):
title: str
description: Union[str, None] = None
class ItemCreate(ItemBase):
pass
class Item(ItemBase):
id: int
owner_id: int
class Config:
orm_mode = True
getter_dict = PeeweeGetterDict
class UserBase(BaseModel):
email: str
class UserCreate(UserBase):
password: str
class User(UserBase):
id: int
is_active: bool
items: List[Item] = []
class Config:
orm_mode = True
getter_dict = PeeweeGetterDict
Tip
Here we are creating the models with an id
.
We didn't explicitly specify an id
attribute in the Peewee models, but Peewee adds one automatically.
We are also adding the magic owner_id
attribute to Item
.
Create a PeeweeGetterDict
for the Pydantic models / schemas¶
When you access a relationship in a Peewee object, like in some_user.items
, Peewee doesn't provide a list
of Item
.
It provides a special custom object of class ModelSelect
.
It's possible to create a list
of its items with list(some_user.items)
.
But the object itself is not a list
. And it's also not an actual Python generator. Because of this, Pydantic doesn't know by default how to convert it to a list
of Pydantic models / schemas.
But recent versions of Pydantic allow providing a custom class that inherits from pydantic.utils.GetterDict
, to provide the functionality used when using the orm_mode = True
to retrieve the values for ORM model attributes.
We are going to create a custom PeeweeGetterDict
class and use it in all the same Pydantic models / schemas that use orm_mode
:
from typing import Any, List, Union
import peewee
from pydantic import BaseModel
from pydantic.utils import GetterDict
class PeeweeGetterDict(GetterDict):
def get(self, key: Any, default: Any = None):
res = getattr(self._obj, key, default)
if isinstance(res, peewee.ModelSelect):
return list(res)
return res
class ItemBase(BaseModel):
title: str
description: Union[str, None] = None
class ItemCreate(ItemBase):
pass
class Item(ItemBase):
id: int
owner_id: int
class Config:
orm_mode = True
getter_dict = PeeweeGetterDict
class UserBase(BaseModel):
email: str
class UserCreate(UserBase):
password: str
class User(UserBase):
id: int
is_active: bool
items: List[Item] = []
class Config:
orm_mode = True
getter_dict = PeeweeGetterDict
Here we are checking if the attribute that is being accessed (e.g. .items
in some_user.items
) is an instance of peewee.ModelSelect
.
And if that's the case, just return a list
with it.
And then we use it in the Pydantic models / schemas that use orm_mode = True
, with the configuration variable getter_dict = PeeweeGetterDict
.
Tip
We only need to create one PeeweeGetterDict
class, and we can use it in all the Pydantic models / schemas.
CRUD utils¶
Now let's see the file sql_app/crud.py
.
Create all the CRUD utils¶
Create all the same CRUD utils as in the SQLAlchemy tutorial, all the code is very similar:
from . import models, schemas
def get_user(user_id: int):
return models.User.filter(models.User.id == user_id).first()
def get_user_by_email(email: str):
return models.User.filter(models.User.email == email).first()
def get_users(skip: int = 0, limit: int = 100):
return list(models.User.select().offset(skip).limit(limit))
def create_user(user: schemas.UserCreate):
fake_hashed_password = user.password + "notreallyhashed"
db_user = models.User(email=user.email, hashed_password=fake_hashed_password)
db_user.save()
return db_user
def get_items(skip: int = 0, limit: int = 100):
return list(models.Item.select().offset(skip).limit(limit))
def create_user_item(item: schemas.ItemCreate, user_id: int):
db_item = models.Item(**item.dict(), owner_id=user_id)
db_item.save()
return db_item
There are some differences with the code for the SQLAlchemy tutorial.
We don't pass a db
attribute around. Instead we use the models directly. This is because the db
object is a global object, that includes all the connection logic. That's why we had to do all the contextvars
updates above.
Aso, when returning several objects, like in get_users
, we directly call list
, like in:
list(models.User.select())
This is for the same reason that we had to create a custom PeeweeGetterDict
. But by returning something that is already a list
instead of the peewee.ModelSelect
the response_model
in the path operation with List[models.User]
(that we'll see later) will work correctly.
Main FastAPI app¶
And now in the file sql_app/main.py
let's integrate and use all the other parts we created before.
Create the database tables¶
In a very simplistic way create the database tables:
import time
from typing import List
from fastapi import Depends, FastAPI, HTTPException
from . import crud, database, models, schemas
from .database import db_state_default
database.db.connect()
database.db.create_tables([models.User, models.Item])
database.db.close()
app = FastAPI()
sleep_time = 10
async def reset_db_state():
database.db._state._state.set(db_state_default.copy())
database.db._state.reset()
def get_db(db_state=Depends(reset_db_state)):
try:
database.db.connect()
yield
finally:
if not database.db.is_closed():
database.db.close()
@app.post("/users/", response_model=schemas.User, dependencies=[Depends(get_db)])
def create_user(user: schemas.UserCreate):
db_user = crud.get_user_by_email(email=user.email)
if db_user:
raise HTTPException(status_code=400, detail="Email already registered")
return crud.create_user(user=user)
@app.get("/users/", response_model=List[schemas.User], dependencies=[Depends(get_db)])
def read_users(skip: int = 0, limit: int = 100):
users = crud.get_users(skip=skip, limit=limit)
return users
@app.get(
"/users/{user_id}", response_model=schemas.User, dependencies=[Depends(get_db)]
)
def read_user(user_id: int):
db_user = crud.get_user(user_id=user_id)
if db_user is None:
raise HTTPException(status_code=404, detail="User not found")
return db_user
@app.post(
"/users/{user_id}/items/",
response_model=schemas.Item,
dependencies=[Depends(get_db)],
)
def create_item_for_user(user_id: int, item: schemas.ItemCreate):
return crud.create_user_item(item=item, user_id=user_id)
@app.get("/items/", response_model=List[schemas.Item], dependencies=[Depends(get_db)])
def read_items(skip: int = 0, limit: int = 100):
items = crud.get_items(skip=skip, limit=limit)
return items
@app.get(
"/slowusers/", response_model=List[schemas.User], dependencies=[Depends(get_db)]
)
def read_slow_users(skip: int = 0, limit: int = 100):
global sleep_time
sleep_time = max(0, sleep_time - 1)
time.sleep(sleep_time) # Fake long processing request
users = crud.get_users(skip=skip, limit=limit)
return users
Create a dependency¶
Create a dependency that will connect the database right at the beginning of a request and disconnect it at the end:
import time
from typing import List
from fastapi import Depends, FastAPI, HTTPException
from . import crud, database, models, schemas
from .database import db_state_default
database.db.connect()
database.db.create_tables([models.User, models.Item])
database.db.close()
app = FastAPI()
sleep_time = 10
async def reset_db_state():
database.db._state._state.set(db_state_default.copy())
database.db._state.reset()
def get_db(db_state=Depends(reset_db_state)):
try:
database.db.connect()
yield
finally:
if not database.db.is_closed():
database.db.close()
@app.post("/users/", response_model=schemas.User, dependencies=[Depends(get_db)])
def create_user(user: schemas.UserCreate):
db_user = crud.get_user_by_email(email=user.email)
if db_user:
raise HTTPException(status_code=400, detail="Email already registered")
return crud.create_user(user=user)
@app.get("/users/", response_model=List[schemas.User], dependencies=[Depends(get_db)])
def read_users(skip: int = 0, limit: int = 100):
users = crud.get_users(skip=skip, limit=limit)
return users
@app.get(
"/users/{user_id}", response_model=schemas.User, dependencies=[Depends(get_db)]
)
def read_user(user_id: int):
db_user = crud.get_user(user_id=user_id)
if db_user is None:
raise HTTPException(status_code=404, detail="User not found")
return db_user
@app.post(
"/users/{user_id}/items/",
response_model=schemas.Item,
dependencies=[Depends(get_db)],
)
def create_item_for_user(user_id: int, item: schemas.ItemCreate):
return crud.create_user_item(item=item, user_id=user_id)
@app.get("/items/", response_model=List[schemas.Item], dependencies=[Depends(get_db)])
def read_items(skip: int = 0, limit: int = 100):
items = crud.get_items(skip=skip, limit=limit)
return items
@app.get(
"/slowusers/", response_model=List[schemas.User], dependencies=[Depends(get_db)]
)
def read_slow_users(skip: int = 0, limit: int = 100):
global sleep_time
sleep_time = max(0, sleep_time - 1)
time.sleep(sleep_time) # Fake long processing request
users = crud.get_users(skip=skip, limit=limit)
return users
Here we have an empty yield
because we are actually not using the database object directly.
It is connecting to the database and storing the connection data in an internal variable that is independent for each request (using the contextvars
tricks from above).
Because the database connection is potentially I/O blocking, this dependency is created with a normal def
function.
And then, in each path operation function that needs to access the database we add it as a dependency.
But we are not using the value given by this dependency (it actually doesn't give any value, as it has an empty yield
). So, we don't add it to the path operation function but to the path operation decorator in the dependencies
parameter:
import time
from typing import List
from fastapi import Depends, FastAPI, HTTPException
from . import crud, database, models, schemas
from .database import db_state_default
database.db.connect()
database.db.create_tables([models.User, models.Item])
database.db.close()
app = FastAPI()
sleep_time = 10
async def reset_db_state():
database.db._state._state.set(db_state_default.copy())
database.db._state.reset()
def get_db(db_state=Depends(reset_db_state)):
try:
database.db.connect()
yield
finally:
if not database.db.is_closed():
database.db.close()
@app.post("/users/", response_model=schemas.User, dependencies=[Depends(get_db)])
def create_user(user: schemas.UserCreate):
db_user = crud.get_user_by_email(email=user.email)
if db_user:
raise HTTPException(status_code=400, detail="Email already registered")
return crud.create_user(user=user)
@app.get("/users/", response_model=List[schemas.User], dependencies=[Depends(get_db)])
def read_users(skip: int = 0, limit: int = 100):
users = crud.get_users(skip=skip, limit=limit)
return users
@app.get(
"/users/{user_id}", response_model=schemas.User, dependencies=[Depends(get_db)]
)
def read_user(user_id: int):
db_user = crud.get_user(user_id=user_id)
if db_user is None:
raise HTTPException(status_code=404, detail="User not found")
return db_user
@app.post(
"/users/{user_id}/items/",
response_model=schemas.Item,
dependencies=[Depends(get_db)],
)
def create_item_for_user(user_id: int, item: schemas.ItemCreate):
return crud.create_user_item(item=item, user_id=user_id)
@app.get("/items/", response_model=List[schemas.Item], dependencies=[Depends(get_db)])
def read_items(skip: int = 0, limit: int = 100):
items = crud.get_items(skip=skip, limit=limit)
return items
@app.get(
"/slowusers/", response_model=List[schemas.User], dependencies=[Depends(get_db)]
)
def read_slow_users(skip: int = 0, limit: int = 100):
global sleep_time
sleep_time = max(0, sleep_time - 1)
time.sleep(sleep_time) # Fake long processing request
users = crud.get_users(skip=skip, limit=limit)
return users
Context variable sub-dependency¶
For all the contextvars
parts to work, we need to make sure we have an independent value in the ContextVar
for each request that uses the database, and that value will be used as the database state (connection, transactions, etc) for the whole request.
For that, we need to create another async
dependency reset_db_state()
that is used as a sub-dependency in get_db()
. It will set the value for the context variable (with just a default dict
) that will be used as the database state for the whole request. And then the dependency get_db()
will store in it the database state (connection, transactions, etc).
import time
from typing import List
from fastapi import Depends, FastAPI, HTTPException
from . import crud, database, models, schemas
from .database import db_state_default
database.db.connect()
database.db.create_tables([models.User, models.Item])
database.db.close()
app = FastAPI()
sleep_time = 10
async def reset_db_state():
database.db._state._state.set(db_state_default.copy())
database.db._state.reset()
def get_db(db_state=Depends(reset_db_state)):
try:
database.db.connect()
yield
finally:
if not database.db.is_closed():
database.db.close()
@app.post("/users/", response_model=schemas.User, dependencies=[Depends(get_db)])
def create_user(user: schemas.UserCreate):
db_user = crud.get_user_by_email(email=user.email)
if db_user:
raise HTTPException(status_code=400, detail="Email already registered")
return crud.create_user(user=user)
@app.get("/users/", response_model=List[schemas.User], dependencies=[Depends(get_db)])
def read_users(skip: int = 0, limit: int = 100):
users = crud.get_users(skip=skip, limit=limit)
return users
@app.get(
"/users/{user_id}", response_model=schemas.User, dependencies=[Depends(get_db)]
)
def read_user(user_id: int):
db_user = crud.get_user(user_id=user_id)
if db_user is None:
raise HTTPException(status_code=404, detail="User not found")
return db_user
@app.post(
"/users/{user_id}/items/",
response_model=schemas.Item,
dependencies=[Depends(get_db)],
)
def create_item_for_user(user_id: int, item: schemas.ItemCreate):
return crud.create_user_item(item=item, user_id=user_id)
@app.get("/items/", response_model=List[schemas.Item], dependencies=[Depends(get_db)])
def read_items(skip: int = 0, limit: int = 100):
items = crud.get_items(skip=skip, limit=limit)
return items
@app.get(
"/slowusers/", response_model=List[schemas.User], dependencies=[Depends(get_db)]
)
def read_slow_users(skip: int = 0, limit: int = 100):
global sleep_time
sleep_time = max(0, sleep_time - 1)
time.sleep(sleep_time) # Fake long processing request
users = crud.get_users(skip=skip, limit=limit)
return users
For the next request, as we will reset that context variable again in the async
dependency reset_db_state()
and then create a new connection in the get_db()
dependency, that new request will have its own database state (connection, transactions, etc).
Tip
As FastAPI is an async framework, one request could start being processed, and before finishing, another request could be received and start processing as well, and it all could be processed in the same thread.
But context variables are aware of these async features, so, a Peewee database state set in the async
dependency reset_db_state()
will keep its own data throughout the entire request.
And at the same time, the other concurrent request will have its own database state that will be independent for the whole request.
Peewee Proxy¶
If you are using a Peewee Proxy, the actual database is at db.obj
.
So, you would reset it with:
async def reset_db_state():
database.db.obj._state._state.set(db_state_default.copy())
database.db.obj._state.reset()
Create your FastAPI path operations¶
Now, finally, here's the standard FastAPI path operations code.
import time
from typing import List
from fastapi import Depends, FastAPI, HTTPException
from . import crud, database, models, schemas
from .database import db_state_default
database.db.connect()
database.db.create_tables([models.User, models.Item])
database.db.close()
app = FastAPI()
sleep_time = 10
async def reset_db_state():
database.db._state._state.set(db_state_default.copy())
database.db._state.reset()
def get_db(db_state=Depends(reset_db_state)):
try:
database.db.connect()
yield
finally:
if not database.db.is_closed():
database.db.close()
@app.post("/users/", response_model=schemas.User, dependencies=[Depends(get_db)])
def create_user(user: schemas.UserCreate):
db_user = crud.get_user_by_email(email=user.email)
if db_user:
raise HTTPException(status_code=400, detail="Email already registered")
return crud.create_user(user=user)
@app.get("/users/", response_model=List[schemas.User], dependencies=[Depends(get_db)])
def read_users(skip: int = 0, limit: int = 100):
users = crud.get_users(skip=skip, limit=limit)
return users
@app.get(
"/users/{user_id}", response_model=schemas.User, dependencies=[Depends(get_db)]
)
def read_user(user_id: int):
db_user = crud.get_user(user_id=user_id)
if db_user is None:
raise HTTPException(status_code=404, detail="User not found")
return db_user
@app.post(
"/users/{user_id}/items/",
response_model=schemas.Item,
dependencies=[Depends(get_db)],
)
def create_item_for_user(user_id: int, item: schemas.ItemCreate):
return crud.create_user_item(item=item, user_id=user_id)
@app.get("/items/", response_model=List[schemas.Item], dependencies=[Depends(get_db)])
def read_items(skip: int = 0, limit: int = 100):
items = crud.get_items(skip=skip, limit=limit)
return items
@app.get(
"/slowusers/", response_model=List[schemas.User], dependencies=[Depends(get_db)]
)
def read_slow_users(skip: int = 0, limit: int = 100):
global sleep_time
sleep_time = max(0, sleep_time - 1)
time.sleep(sleep_time) # Fake long processing request
users = crud.get_users(skip=skip, limit=limit)
return users
About def
vs async def
¶
The same as with SQLAlchemy, we are not doing something like:
user = await models.User.select().first()
...but instead we are using:
user = models.User.select().first()
So, again, we should declare the path operation functions and the dependency without async def
, just with a normal def
, as:
# Something goes here
def read_users(skip: int = 0, limit: int = 100):
# Something goes here
Testing Peewee with async¶
This example includes an extra path operation that simulates a long processing request with time.sleep(sleep_time)
.
It will have the database connection open at the beginning and will just wait some seconds before replying back. And each new request will wait one second less.
This will easily let you test that your app with Peewee and FastAPI is behaving correctly with all the stuff about threads.
If you want to check how Peewee would break your app if used without modification, go the the sql_app/database.py
file and comment the line:
# db._state = PeeweeConnectionState()
And in the file sql_app/main.py
file, comment the body of the async
dependency reset_db_state()
and replace it with a pass
:
async def reset_db_state():
# database.db._state._state.set(db_state_default.copy())
# database.db._state.reset()
pass
Then run your app with Uvicorn:
$ uvicorn sql_app.main:app --reload
<span style="color: green;">INFO</span>: Uvicorn running on http://127.0.0.1:8000 (Press CTRL+C to quit)
Open your browser at http://127.0.0.1:8000/docs and create a couple of users.
Then open 10 tabs at http://127.0.0.1:8000/docs#/default/read_slow_users_slowusers__get at the same time.
Go to the path operation "Get /slowusers/
" in all of the tabs. Use the "Try it out" button and execute the request in each tab, one right after the other.
The tabs will wait for a bit and then some of them will show Internal Server Error
.
What happens¶
The first tab will make your app create a connection to the database and wait for some seconds before replying back and closing the database connection.
Then, for the request in the next tab, your app will wait for one second less, and so on.
This means that it will end up finishing some of the last tabs' requests earlier than some of the previous ones.
Then one the last requests that wait less seconds will try to open a database connection, but as one of those previous requests for the other tabs will probably be handled in the same thread as the first one, it will have the same database connection that is already open, and Peewee will throw an error and you will see it in the terminal, and the response will have an Internal Server Error
.
This will probably happen for more than one of those tabs.
If you had multiple clients talking to your app exactly at the same time, this is what could happen.
And as your app starts to handle more and more clients at the same time, the waiting time in a single request needs to be shorter and shorter to trigger the error.
Fix Peewee with FastAPI¶
Now go back to the file sql_app/database.py
, and uncomment the line:
db._state = PeeweeConnectionState()
And in the file sql_app/main.py
file, uncomment the body of the async
dependency reset_db_state()
:
async def reset_db_state():
database.db._state._state.set(db_state_default.copy())
database.db._state.reset()
Terminate your running app and start it again.
Repeat the same process with the 10 tabs. This time all of them will wait and you will get all the results without errors.
...You fixed it!
Review all the files¶
Remember you should have a directory named my_super_project
(or however you want) that contains a sub-directory called sql_app
.
sql_app
should have the following files:
-
sql_app/__init__.py
: is an empty file. -
sql_app/database.py
:
from contextvars import ContextVar
import peewee
DATABASE_NAME = "test.db"
db_state_default = {"closed": None, "conn": None, "ctx": None, "transactions": None}
db_state = ContextVar("db_state", default=db_state_default.copy())
class PeeweeConnectionState(peewee._ConnectionState):
def __init__(self, **kwargs):
super().__setattr__("_state", db_state)
super().__init__(**kwargs)
def __setattr__(self, name, value):
self._state.get()[name] = value
def __getattr__(self, name):
return self._state.get()[name]
db = peewee.SqliteDatabase(DATABASE_NAME, check_same_thread=False)
db._state = PeeweeConnectionState()
sql_app/models.py
:
import peewee
from .database import db
class User(peewee.Model):
email = peewee.CharField(unique=True, index=True)
hashed_password = peewee.CharField()
is_active = peewee.BooleanField(default=True)
class Meta:
database = db
class Item(peewee.Model):
title = peewee.CharField(index=True)
description = peewee.CharField(index=True)
owner = peewee.ForeignKeyField(User, backref="items")
class Meta:
database = db
sql_app/schemas.py
:
from typing import Any, List, Union
import peewee
from pydantic import BaseModel
from pydantic.utils import GetterDict
class PeeweeGetterDict(GetterDict):
def get(self, key: Any, default: Any = None):
res = getattr(self._obj, key, default)
if isinstance(res, peewee.ModelSelect):
return list(res)
return res
class ItemBase(BaseModel):
title: str
description: Union[str, None] = None
class ItemCreate(ItemBase):
pass
class Item(ItemBase):
id: int
owner_id: int
class Config:
orm_mode = True
getter_dict = PeeweeGetterDict
class UserBase(BaseModel):
email: str
class UserCreate(UserBase):
password: str
class User(UserBase):
id: int
is_active: bool
items: List[Item] = []
class Config:
orm_mode = True
getter_dict = PeeweeGetterDict
sql_app/crud.py
:
from . import models, schemas
def get_user(user_id: int):
return models.User.filter(models.User.id == user_id).first()
def get_user_by_email(email: str):
return models.User.filter(models.User.email == email).first()
def get_users(skip: int = 0, limit: int = 100):
return list(models.User.select().offset(skip).limit(limit))
def create_user(user: schemas.UserCreate):
fake_hashed_password = user.password + "notreallyhashed"
db_user = models.User(email=user.email, hashed_password=fake_hashed_password)
db_user.save()
return db_user
def get_items(skip: int = 0, limit: int = 100):
return list(models.Item.select().offset(skip).limit(limit))
def create_user_item(item: schemas.ItemCreate, user_id: int):
db_item = models.Item(**item.dict(), owner_id=user_id)
db_item.save()
return db_item
sql_app/main.py
:
import time
from typing import List
from fastapi import Depends, FastAPI, HTTPException
from . import crud, database, models, schemas
from .database import db_state_default
database.db.connect()
database.db.create_tables([models.User, models.Item])
database.db.close()
app = FastAPI()
sleep_time = 10
async def reset_db_state():
database.db._state._state.set(db_state_default.copy())
database.db._state.reset()
def get_db(db_state=Depends(reset_db_state)):
try:
database.db.connect()
yield
finally:
if not database.db.is_closed():
database.db.close()
@app.post("/users/", response_model=schemas.User, dependencies=[Depends(get_db)])
def create_user(user: schemas.UserCreate):
db_user = crud.get_user_by_email(email=user.email)
if db_user:
raise HTTPException(status_code=400, detail="Email already registered")
return crud.create_user(user=user)
@app.get("/users/", response_model=List[schemas.User], dependencies=[Depends(get_db)])
def read_users(skip: int = 0, limit: int = 100):
users = crud.get_users(skip=skip, limit=limit)
return users
@app.get(
"/users/{user_id}", response_model=schemas.User, dependencies=[Depends(get_db)]
)
def read_user(user_id: int):
db_user = crud.get_user(user_id=user_id)
if db_user is None:
raise HTTPException(status_code=404, detail="User not found")
return db_user
@app.post(
"/users/{user_id}/items/",
response_model=schemas.Item,
dependencies=[Depends(get_db)],
)
def create_item_for_user(user_id: int, item: schemas.ItemCreate):
return crud.create_user_item(item=item, user_id=user_id)
@app.get("/items/", response_model=List[schemas.Item], dependencies=[Depends(get_db)])
def read_items(skip: int = 0, limit: int = 100):
items = crud.get_items(skip=skip, limit=limit)
return items
@app.get(
"/slowusers/", response_model=List[schemas.User], dependencies=[Depends(get_db)]
)
def read_slow_users(skip: int = 0, limit: int = 100):
global sleep_time
sleep_time = max(0, sleep_time - 1)
time.sleep(sleep_time) # Fake long processing request
users = crud.get_users(skip=skip, limit=limit)
return users
Technical Details¶
Warning
These are very technical details that you probably don't need.
The problem¶
Peewee uses threading.local
by default to store it's database "state" data (connection, transactions, etc).
threading.local
creates a value exclusive to the current thread, but an async framework would run all the code (e.g. for each request) in the same thread, and possibly not in order.
On top of that, an async framework could run some sync code in a threadpool (using asyncio.run_in_executor
), but belonging to the same request.
This means that, with Peewee's current implementation, multiple tasks could be using the same threading.local
variable and end up sharing the same connection and data (that they shouldn't), and at the same time, if they execute sync I/O-blocking code in a threadpool (as with normal def
functions in FastAPI, in path operations and dependencies), that code won't have access to the database state variables, even while it's part of the same request and it should be able to get access to the same database state.
Context variables¶
Python 3.7 has contextvars
that can create a local variable very similar to threading.local
, but also supporting these async features.
There are several things to have in mind.
The ContextVar
has to be created at the top of the module, like:
some_var = ContextVar("some_var", default="default value")
To set a value used in the current "context" (e.g. for the current request) use:
some_var.set("new value")
To get a value anywhere inside of the context (e.g. in any part handling the current request) use:
some_var.get()
Set context variables in the async
dependency reset_db_state()
¶
If some part of the async code sets the value with some_var.set("updated in function")
(e.g. like the async
dependency), the rest of the code in it and the code that goes after (including code inside of async
functions called with await
) will see that new value.
So, in our case, if we set the Peewee state variable (with a default dict
) in the async
dependency, all the rest of the internal code in our app will see this value and will be able to reuse it for the whole request.
And the context variable would be set again for the next request, even if they are concurrent.
Set database state in the dependency get_db()
¶
As get_db()
is a normal def
function, FastAPI will make it run in a threadpool, with a copy of the "context", holding the same value for the context variable (the dict
with the reset database state). Then it can add database state to that dict
, like the connection, etc.
But if the value of the context variable (the default dict
) was set in that normal def
function, it would create a new value that would stay only in that thread of the threadpool, and the rest of the code (like the path operation functions) wouldn't have access to it. In get_db()
we can only set values in the dict
, but not the entire dict
itself.
So, we need to have the async
dependency reset_db_state()
to set the dict
in the context variable. That way, all the code has access to the same dict
for the database state for a single request.
Connect and disconnect in the dependency get_db()
¶
Then the next question would be, why not just connect and disconnect the database in the async
dependency itself, instead of in get_db()
?
The async
dependency has to be async
for the context variable to be preserved for the rest of the request, but creating and closing the database connection is potentially blocking, so it could degrade performance if it was there.
So we also need the normal def
dependency get_db()
.