My django project uses django-helpdesk app.
This app has Ticket model.
My app got a Client model, which should have one to many relationship with ticket- so I could for example list all tickets concerning specific client.
Normally I would add models.ForeignKey(Client) to Ticket
But it's an external app and I don't want to modify it (future update problems etc.).
I wold have no problem with ManyToMany or OneToOne but don't know how to do it with ManyToOne (many tickets from external app to one Client from my app)
Even more hacky solution: You can do the following in the module level code after you Client class:
class Client(models.Model):
...
client = models.ForeignKey(Client, related_name='tickets')
client.contribute_to_class(Ticket, name='client')
I haven't fully tested it (I didn't do any actual database migrations), but the correct descriptors (ReverseSingleRelatedObjectDescriptor for Ticket and ForeignRelatedObjectsDescriptor for Client) get added to the class, and South recognizes the new fields. So far it seems to work just like a regular ForeignKey.
EDIT: Actually not even that hacky. This is exactly how Django sets up foreign keys across classes. It just reverses the process by adding the field when the reverse related class is built. It won't raise an error if any of the original fields on either model is shadowed. Just make sure you don't do that, as it could potentially break your code. Other than that, I don't think there should be any issues.
There are (at least) two ways to accomplish it:
More elegant solution: Use a TicketProfile class which has a one-to-one relation to Ticket, and put the Client foreign key into it.
Hacky solution: Use a many-to-many relation, and manually edit the automatically created table and make ticket_id unique.
My background with designing data stores comes from Core Data on iOS, which supports properties having a one-to-many relationship with another entity.
I'm working on an App Engine project which currently has three entity types:
User, which represents a person using the app.
Project, which represents a project. A User may be associated with many projects.
Post, which is the main content behind a Project. A Project may have many posts.
Currently, User has a property, projects, that is a one-to-many relationship to Project entities. Project has a property, posts, that is a one-to-many relationship to Post entities.
In this case, is Datastore's Reference Property or NDB's Structured Property better for the job (and how are the two conceptually different)? Is there a better way to structure my data?
By reference property you probably mean Key Property. This is a reference to another datastore entity. It is present in both db and ndb APIs. Using these, you can model a many to one relationship by pointing many entities to the key of another entity.
Structured property is a completely different beast. It allows you to define a data structure, and then include it within another entity.
Here's an example from the docs where you include multiple addresses for a single contact:
class Address(ndb.Model):
type = ndb.StringProperty() # E.g., 'home', 'work'
street = ndb.StringProperty()
city = ndb.StringProperty()
class Contact(ndb.Model):
name = ndb.StringProperty()
addresses = ndb.StructuredProperty(Address, repeated=True)
guido = Contact(name='Guido',
addresses=[Address(type='home',
city='Amsterdam'),
Address(type='work',
street='Spear St',
city='SF')])
guido.put()
For your specific application I'd recommend using NDB (it's always best to use the latest version of the api available), with the following:
Post model included under Project model as a repeated structured property.
Users include a repeated KeyProperty that contains the keys of the Projects they have permissions to.
To make it a bit more complex, you can create a another model to represent projects and permissions/roles, and then include that as a repeated structured property within the user model.
The main reason you want to hang on to the keys, is to keep the data accessible in light of HRDs eventual consistency.
Let me know if you need any more help on this.
EDIT:
To clarify, here's the proposed structure:
Models:
User
User-Project-Mapping (optional, needed to handle permissions)
Project
Post
User model should contain User-Project-Mapping as repeated structured property.
Project model should contain Post as repeated structured property.
User-Project-Mapping only needs to contain Key reference to the Project and relevant permissions representation.
Since this sounds like a commercial project, if you'd like further help with this, I'll gladly consult for you. Hope you have enough to succeed!
There is another point that was not mentioned and might be relevant: entities inserted in a StructuredProperty "are not full-fledged entities", as mentioned in this part of the docs. Below is the complete quote (it refers to the same example mentioned in the answer by #Sologoub):
Although the Address instances are defined using the same
syntax as for model classes, they are not full-fledged entities. They
don't have their own keys in the Datastore. They cannot be retrieved
independently of the Contact entity to which they belong.
This may cast some limitations in the design given that you cannot reuse an entity's property without duplicating data. The KeyProperty, on the other side, refers to another entity's key and therefore represents entities relationship in a more "relational" way. And KeyProperties can also be repeated: just include the repeated=True parameter.
I am writing a project in Django and I see that 80% of the code is in the file models.py. This code is confusing and, after a certain time, I cease to understand what is really happening.
Here is what bothers me:
I find it ugly that my model level (which was supposed to be
responsible only for the work with data from a database) is also
sending email, walking on API to other services, etc.
Also, I find it unacceptable to place business logic in the view, because
this way it becomes difficult to control. For example, in my
application there are at least three ways to create new
instances of User, but technically it should create them uniformly.
I do not always notice when the methods and
properties of my models become non-deterministic and when they develop
side effects.
Here is a simple example. At first, the User model was like this:
class User(db.Models):
def get_present_name(self):
return self.name or 'Anonymous'
def activate(self):
self.status = 'activated'
self.save()
Over time, it turned into this:
class User(db.Models):
def get_present_name(self):
# property became non-deterministic in terms of database
# data is taken from another service by api
return remote_api.request_user_name(self.uid) or 'Anonymous'
def activate(self):
# method now has a side effect (send message to user)
self.status = 'activated'
self.save()
send_mail('Your account is activated!', '…', [self.email])
What I want is to separate entities in my code:
Database level entities, i.e. database level logic: What kind of data does my application store?
application level entities, i.e. business level logic: What does my application do?
What are the good practices to implement such an approach that can be applied in Django?
It seems like you are asking about the difference between the data model and the domain model – the latter is where you can find the business logic and entities as perceived by your end user, the former is where you actually store your data.
Furthermore, I've interpreted the 3rd part of your question as: how to notice failure to keep these models separate.
These are two very different concepts and it's always hard to keep them separate. However, there are some common patterns and tools that can be used for this purpose.
About the Domain Model
The first thing you need to recognize is that your domain model is not really about data; it is about actions and questions such as "activate this user", "deactivate this user", "which users are currently activated?", and "what is this user's name?". In classical terms: it's about queries and commands.
Thinking in Commands
Let's start by looking at the commands in your example: "activate this user" and "deactivate this user". The nice thing about commands is that they can easily be expressed by small given-when-then scenario's:
given an inactive user
when the admin activates this user
then the user becomes active
and a confirmation e-mail is sent to the user
and an entry is added to the system log
(etc. etc.)
Such scenario's are useful to see how different parts of your infrastructure can be affected by a single command – in this case your database (some kind of 'active' flag), your mail server, your system log, etc.
Such scenario's also really help you in setting up a Test Driven Development environment.
And finally, thinking in commands really helps you create a task-oriented application. Your users will appreciate this :-)
Expressing Commands
Django provides two easy ways of expressing commands; they are both valid options and it is not unusual to mix the two approaches.
The service layer
The service module has already been described by #Hedde. Here you define a separate module and each command is represented as a function.
services.py
def activate_user(user_id):
user = User.objects.get(pk=user_id)
# set active flag
user.active = True
user.save()
# mail user
send_mail(...)
# etc etc
Using forms
The other way is to use a Django Form for each command. I prefer this approach, because it combines multiple closely related aspects:
execution of the command (what does it do?)
validation of the command parameters (can it do this?)
presentation of the command (how can I do this?)
forms.py
class ActivateUserForm(forms.Form):
user_id = IntegerField(widget = UsernameSelectWidget, verbose_name="Select a user to activate")
# the username select widget is not a standard Django widget, I just made it up
def clean_user_id(self):
user_id = self.cleaned_data['user_id']
if User.objects.get(pk=user_id).active:
raise ValidationError("This user cannot be activated")
# you can also check authorizations etc.
return user_id
def execute(self):
"""
This is not a standard method in the forms API; it is intended to replace the
'extract-data-from-form-in-view-and-do-stuff' pattern by a more testable pattern.
"""
user_id = self.cleaned_data['user_id']
user = User.objects.get(pk=user_id)
# set active flag
user.active = True
user.save()
# mail user
send_mail(...)
# etc etc
Thinking in Queries
You example did not contain any queries, so I took the liberty of making up a few useful queries. I prefer to use the term "question", but queries is the classical terminology. Interesting queries are: "What is the name of this user?", "Can this user log in?", "Show me a list of deactivated users", and "What is the geographical distribution of deactivated users?"
Before embarking on answering these queries, you should always ask yourself this question, is this:
a presentational query just for my templates, and/or
a business logic query tied to executing my commands, and/or
a reporting query.
Presentational queries are merely made to improve the user interface. The answers to business logic queries directly affect the execution of your commands. Reporting queries are merely for analytical purposes and have looser time constraints. These categories are not mutually exclusive.
The other question is: "do I have complete control over the answers?" For example, when querying the user's name (in this context) we do not have any control over the outcome, because we rely on an external API.
Making Queries
The most basic query in Django is the use of the Manager object:
User.objects.filter(active=True)
Of course, this only works if the data is actually represented in your data model. This is not always the case. In those cases, you can consider the options below.
Custom tags and filters
The first alternative is useful for queries that are merely presentational: custom tags and template filters.
template.html
<h1>Welcome, {{ user|friendly_name }}</h1>
template_tags.py
#register.filter
def friendly_name(user):
return remote_api.get_cached_name(user.id)
Query methods
If your query is not merely presentational, you could add queries to your services.py (if you are using that), or introduce a queries.py module:
queries.py
def inactive_users():
return User.objects.filter(active=False)
def users_called_publysher():
for user in User.objects.all():
if remote_api.get_cached_name(user.id) == "publysher":
yield user
Proxy models
Proxy models are very useful in the context of business logic and reporting. You basically define an enhanced subset of your model. You can override a Manager’s base QuerySet by overriding the Manager.get_queryset() method.
models.py
class InactiveUserManager(models.Manager):
def get_queryset(self):
query_set = super(InactiveUserManager, self).get_queryset()
return query_set.filter(active=False)
class InactiveUser(User):
"""
>>> for user in InactiveUser.objects.all():
… assert user.active is False
"""
objects = InactiveUserManager()
class Meta:
proxy = True
Query models
For queries that are inherently complex, but are executed quite often, there is the possibility of query models. A query model is a form of denormalization where relevant data for a single query is stored in a separate model. The trick of course is to keep the denormalized model in sync with the primary model. Query models can only be used if changes are entirely under your control.
models.py
class InactiveUserDistribution(models.Model):
country = CharField(max_length=200)
inactive_user_count = IntegerField(default=0)
The first option is to update these models in your commands. This is very useful if these models are only changed by one or two commands.
forms.py
class ActivateUserForm(forms.Form):
# see above
def execute(self):
# see above
query_model = InactiveUserDistribution.objects.get_or_create(country=user.country)
query_model.inactive_user_count -= 1
query_model.save()
A better option would be to use custom signals. These signals are of course emitted by your commands. Signals have the advantage that you can keep multiple query models in sync with your original model. Furthermore, signal processing can be offloaded to background tasks, using Celery or similar frameworks.
signals.py
user_activated = Signal(providing_args = ['user'])
user_deactivated = Signal(providing_args = ['user'])
forms.py
class ActivateUserForm(forms.Form):
# see above
def execute(self):
# see above
user_activated.send_robust(sender=self, user=user)
models.py
class InactiveUserDistribution(models.Model):
# see above
#receiver(user_activated)
def on_user_activated(sender, **kwargs):
user = kwargs['user']
query_model = InactiveUserDistribution.objects.get_or_create(country=user.country)
query_model.inactive_user_count -= 1
query_model.save()
Keeping it clean
When using this approach, it becomes ridiculously easy to determine if your code stays clean. Just follow these guidelines:
Does my model contain methods that do more than managing database state? You should extract a command.
Does my model contain properties that do not map to database fields? You should extract a query.
Does my model reference infrastructure that is not my database (such as mail)? You should extract a command.
The same goes for views (because views often suffer from the same problem).
Does my view actively manage database models? You should extract a command.
Some References
Django documentation: proxy models
Django documentation: signals
Architecture: Domain Driven Design
I usually implement a service layer in between views and models. This acts like your project's API and gives you a good helicopter view of what is going on. I inherited this practice from a colleague of mine that uses this layering technique a lot with Java projects (JSF), e.g:
models.py
class Book:
author = models.ForeignKey(User)
title = models.CharField(max_length=125)
class Meta:
app_label = "library"
services.py
from library.models import Book
def get_books(limit=None, **filters):
""" simple service function for retrieving books can be widely extended """
return Book.objects.filter(**filters)[:limit] # list[:None] will return the entire list
views.py
from library.services import get_books
class BookListView(ListView):
""" simple view, e.g. implement a _build and _apply filters function """
queryset = get_books()
Mind you, I usually take models, views and services to module level and
separate even further depending on the project's size
First of all, Don't repeat yourself.
Then, please be careful not to overengineer, sometimes it is just a waste of time, and makes someone lose focus on what is important. Review the zen of python from time to time.
Take a look at active projects
more people = more need to organize properly
the django repository they have a straightforward structure.
the pip repository they have a straigtforward directory structure.
the fabric repository is also a good one to look at.
you can place all your models under yourapp/models/logicalgroup.py
e.g User, Group and related models can go under yourapp/models/users.py
e.g Poll, Question, Answer ... could go under yourapp/models/polls.py
load what you need in __all__ inside of yourapp/models/__init__.py
More about MVC
model is your data
this includes your actual data
this also includes your session / cookie / cache / fs / index data
user interacts with controller to manipulate the model
this could be an API, or a view that saves/updates your data
this can be tuned with request.GET / request.POST ...etc
think paging or filtering too.
the data updates the view
the templates take the data and format it accordingly
APIs even w/o templates are part of the view; e.g. tastypie or piston
this should also account for the middleware.
Take advantage of middleware / templatetags
If you need some work to be done for each request, middleware is one way to go.
e.g. adding timestamps
e.g. updating metrics about page hits
e.g. populating a cache
If you have snippets of code that always reoccur for formatting objects, templatetags are good.
e.g. active tab / url breadcrumbs
Take advantage of model managers
creating User can go in a UserManager(models.Manager).
gory details for instances should go on the models.Model.
gory details for queryset could go in a models.Manager.
you might want to create a User one at a time, so you may think that it should live on the model itself, but when creating the object, you probably don't have all the details:
Example:
class UserManager(models.Manager):
def create_user(self, username, ...):
# plain create
def create_superuser(self, username, ...):
# may set is_superuser field.
def activate(self, username):
# may use save() and send_mail()
def activate_in_bulk(self, queryset):
# may use queryset.update() instead of save()
# may use send_mass_mail() instead of send_mail()
Make use of forms where possible
A lot of boilerplate code can be eliminated if you have forms that map to a model. The ModelForm documentation is pretty good. Separating code for forms from model code can be good if you have a lot of customization (or sometimes avoid cyclic import errors for more advanced uses).
Use management commands when possible
e.g. yourapp/management/commands/createsuperuser.py
e.g. yourapp/management/commands/activateinbulk.py
if you have business logic, you can separate it out
django.contrib.auth uses backends, just like db has a backend...etc.
add a setting for your business logic (e.g. AUTHENTICATION_BACKENDS)
you could use django.contrib.auth.backends.RemoteUserBackend
you could use yourapp.backends.remote_api.RemoteUserBackend
you could use yourapp.backends.memcached.RemoteUserBackend
delegate the difficult business logic to the backend
make sure to set the expectation right on the input/output.
changing business logic is as simple as changing a setting :)
backend example:
class User(db.Models):
def get_present_name(self):
# property became not deterministic in terms of database
# data is taken from another service by api
return remote_api.request_user_name(self.uid) or 'Anonymous'
could become:
class User(db.Models):
def get_present_name(self):
for backend in get_backends():
try:
return backend.get_present_name(self)
except: # make pylint happy.
pass
return None
more about design patterns
there's already a good question about design patterns
a very good video about practical design patterns
django's backends are obvious use of delegation design pattern.
more about interface boundaries
Is the code you want to use really part of the models? -> yourapp.models
Is the code part of business logic? -> yourapp.vendor
Is the code part of generic tools / libs? -> yourapp.libs
Is the code part of business logic libs? -> yourapp.libs.vendor or yourapp.vendor.libs
Here is a good one: can you test your code independently?
yes, good :)
no, you may have an interface problem
when there is clear separation, unittest should be a breeze with the use of mocking
Is the separation logical?
yes, good :)
no, you may have trouble testing those logical concepts separately.
Do you think you will need to refactor when you get 10x more code?
yes, no good, no bueno, refactor could be a lot of work
no, that's just awesome!
In short, you could have
yourapp/core/backends.py
yourapp/core/models/__init__.py
yourapp/core/models/users.py
yourapp/core/models/questions.py
yourapp/core/backends.py
yourapp/core/forms.py
yourapp/core/handlers.py
yourapp/core/management/commands/__init__.py
yourapp/core/management/commands/closepolls.py
yourapp/core/management/commands/removeduplicates.py
yourapp/core/middleware.py
yourapp/core/signals.py
yourapp/core/templatetags/__init__.py
yourapp/core/templatetags/polls_extras.py
yourapp/core/views/__init__.py
yourapp/core/views/users.py
yourapp/core/views/questions.py
yourapp/core/signals.py
yourapp/lib/utils.py
yourapp/lib/textanalysis.py
yourapp/lib/ratings.py
yourapp/vendor/backends.py
yourapp/vendor/morebusinesslogic.py
yourapp/vendor/handlers.py
yourapp/vendor/middleware.py
yourapp/vendor/signals.py
yourapp/tests/test_polls.py
yourapp/tests/test_questions.py
yourapp/tests/test_duplicates.py
yourapp/tests/test_ratings.py
or anything else that helps you; finding the interfaces you need and the boundaries will help you.
Django employs a slightly modified kind of MVC. There's no concept of a "controller" in Django. The closest proxy is a "view", which tends to cause confusion with MVC converts because in MVC a view is more like Django's "template".
In Django, a "model" is not merely a database abstraction. In some respects, it shares duty with the Django's "view" as the controller of MVC. It holds the entirety of behavior associated with an instance. If that instance needs to interact with an external API as part of it's behavior, then that's still model code. In fact, models aren't required to interact with the database at all, so you could conceivable have models that entirely exist as an interactive layer to an external API. It's a much more free concept of a "model".
In Django, MVC structure is as Chris Pratt said, different from classical MVC model used in other frameworks, I think the main reason for doing this is avoiding a too strict application structure, like happens in others MVC frameworks like CakePHP.
In Django, MVC was implemented in the following way:
View layer is splitted in two. The views should be used only to manage HTTP requests, they are called and respond to them. Views communicate with the rest of your application (forms, modelforms, custom classes, of in simple cases directly with models).
To create the interface we use Templates. Templates are string-like to Django, it maps a context into them, and this context was communicated to the view by the application (when view asks).
Model layer gives encapsulation, abstraction, validation, intelligence and makes your data object-oriented (they say someday DBMS will also). This doesn't means that you should make huge models.py files (in fact a very good advice is to split your models in different files, put them into a folder called 'models', make an '__init__.py' file into this folder where you import all your models and finally use the attribute 'app_label' of models.Model class). Model should abstract you from operating with data, it will make your application simpler. You should also, if required, create external classes, like "tools" for your models.You can also use heritage in models, setting the 'abstract' attribute of your model's Meta class to 'True'.
Where is the rest? Well, small web applications generally are a sort of an interface to data, in some small program cases using views to query or insert data would be enough. More common cases will use Forms or ModelForms, which are actually "controllers". This is not other than a practical solution to a common problem, and a very fast one. It's what a website use to do.
If Forms are not enogh for you, then you should create your own classes to do the magic, a very good example of this is admin application: you can read ModelAmin code, this actually works as a controller. There is not a standard structure, I suggest you to examine existing Django apps, it depends on each case. This is what Django developers intended, you can add xml parser class, an API connector class, add Celery for performing tasks, twisted for a reactor-based application, use only the ORM, make a web service, modify the admin application and more... It's your responsability to make good quality code, respect MVC philosophy or not, make it module based and creating your own abstraction layers. It's very flexible.
My advice: read as much code as you can, there are lots of django applications around, but don't take them so seriously. Each case is different, patterns and theory helps, but not always, this is an imprecise cience, django just provide you good tools that you can use to aliviate some pains (like admin interface, web form validation, i18n, observer pattern implementation, all the previously mentioned and others), but good designs come from experienced designers.
PS.: use 'User' class from auth application (from standard django), you can make for example user profiles, or at least read its code, it will be useful for your case.
An old question, but I'd like to offer my solution anyway. It's based on acceptance that model objects too require some additional functionality while it's awkward to place it within the models.py. Heavy business logic may be written separately depending on personal taste, but I at least like the model to do everything related to itself. This solution also supports those who like to have all the logic placed within models themselves.
As such, I devised a hack that allows me to separate logic from model definitions and still get all the hinting from my IDE.
The advantages should be obvious, but this lists a few that I have observed:
DB definitions remain just that - no logic "garbage" attached
Model-related logic is all placed neatly in one place
All the services (forms, REST, views) have a single access point to logic
Best of all: I did not have to rewrite any code once I realised that my models.py became too cluttered and had to separate the logic away. The separation is smooth and iterative: I could do a function at a time or entire class or the entire models.py.
I have been using this with Python 3.4 and greater and Django 1.8 and greater.
app/models.py
....
from app.logic.user import UserLogic
class User(models.Model, UserLogic):
field1 = models.AnyField(....)
... field definitions ...
app/logic/user.py
if False:
# This allows the IDE to know about the User model and its member fields
from main.models import User
class UserLogic(object):
def logic_function(self: 'User'):
... code with hinting working normally ...
The only thing I can't figure out is how to make my IDE (PyCharm in this case) recognise that UserLogic is actually User model. But since this is obviously a hack, I'm quite happy to accept the little nuisance of always specifying type for self parameter.
I would have to agree with you. There are a lot of possibilities in django but best place to start is reviewing Django's design philosophy.
Calling an API from a model property would not be ideal, it seems like it would make more sense to do something like this in the view and possibly create a service layer to keep things dry. If the call to the API is non-blocking and the call is an expensive one, sending the request to a service worker (a worker that consumes from a queue) might make sense.
As per Django's design philosophy models encapsulate every aspect of an "object". So all business logic related to that object should live there:
Include all relevant domain logic
Models should encapsulate every aspect of an “object,” following Martin Fowler’s Active Record design pattern.
The side effects you describe are apparent, the logic here could be better broken down into Querysets and managers. Here is an example:
models.py
import datetime
from djongo import models
from django.db.models.query import QuerySet
from django.contrib import admin
from django.db import transaction
class MyUser(models.Model):
present_name = models.TextField(null=False, blank=True)
status = models.TextField(null=False, blank=True)
last_active = models.DateTimeField(auto_now=True, editable=False)
# As mentioned you could put this in a template tag to pull it
# from cache there. Depending on how it is used, it could be
# retrieved from within the admin view or from a custom view
# if that is the only place you will use it.
#def get_present_name(self):
# # property became non-deterministic in terms of database
# # data is taken from another service by api
# return remote_api.request_user_name(self.uid) or 'Anonymous'
# Moved to admin as an action
# def activate(self):
# # method now has a side effect (send message to user)
# self.status = 'activated'
# self.save()
# # send email via email service
# #send_mail('Your account is activated!', '…', [self.email])
class Meta:
ordering = ['-id'] # Needed for DRF pagination
def __unicode__(self):
return '{}'.format(self.pk)
class MyUserRegistrationQuerySet(QuerySet):
def for_inactive_users(self):
new_date = datetime.datetime.now() - datetime.timedelta(days=3*365) # 3 Years ago
return self.filter(last_active__lte=new_date.year)
def by_user_id(self, user_ids):
return self.filter(id__in=user_ids)
class MyUserRegistrationManager(models.Manager):
def get_query_set(self):
return MyUserRegistrationQuerySet(self.model, using=self._db)
def with_no_activity(self):
return self.get_query_set().for_inactive_users()
admin.py
# Then in model admin
class MyUserRegistrationAdmin(admin.ModelAdmin):
actions = (
'send_welcome_emails',
)
def send_activate_emails(self, request, queryset):
rows_affected = 0
for obj in queryset:
with transaction.commit_on_success():
# send_email('welcome_email', request, obj) # send email via email service
obj.status = 'activated'
obj.save()
rows_affected += 1
self.message_user(request, 'sent %d' % rows_affected)
admin.site.register(MyUser, MyUserRegistrationAdmin)
I'm mostly agree with chosen answer (https://stackoverflow.com/a/12857584/871392), but want to add option in Making Queries section.
One can define QuerySet classes for models for make filter queries and so on. After that you can proxy this queryset class for model's manager, like build-in Manager and QuerySet classes do.
Although, if you had to query several data models to get one domain model, it seems more reasonable to me to put this in separate module like suggested before.
Most comprehensive article on the different options with pros and cons:
Idea #1: Fat Models
Idea #2: Putting Business Logic in Views/Forms
Idea #3: Services
Idea #4: QuerySets/Managers
Conclusion
Source:
https://sunscrapers.com/blog/where-to-put-business-logic-django/
I'm working on a user based, social networking type of web application in Django. It's my first one so I would like to make sure I'm using some good practices.
Currently the web app supports two kinds of users. This is represented by two different Groups. When I register a user I assign them to one of these two groups. I also have two apps, one for each type of user. The apps handle whatever things are distinct to a particular type of user. I have another app that handles the actual authentication. This app uses Django's built in User type and assigns them a UserProfile. The two different types of users have their own profiles which extend/inherit from UserProfile.
This works reasonably well, and is fairly reusable since the authentication app can pull the user type from the url and figure out which type of user to create. Since the groups are named conveniently, they can be added to the correct group too.
Is this the best way or are there more preferred, tried and true ways to handle this? It seems like a pretty common enough scenario. I don't want to continue incorrectly reinventing the wheel if I don't have to.
I was thinking of adding another app called, common, or something which would handle things that are common to all users. For example, viewing a users profile page might be something anyone who is logged in might want to do, regardless of what type of user they are.
Thanks!
Easy part first, with 2) you're spot on. That would be the simplest and most effective way of doing that. It makes sense instead of replicating functionality across both applications to have one app that handles things that are common to both user types.
Back to 1)
With both profiles extending from UserProfile, you'd run into the issue of (if you were using get_profile() on a User object - see http://docs.djangoproject.com/en/dev/topics/auth/#storing-additional-information-about-users) that you'd get back just a UserProfile object, not knowing which group the user actually belongs to based on the object received. This is because they both extend UserProfile but UserProfile would not be able to be (I believe) abstract, because you want every User to have a pointer to a UserProfile object which may actually be a UserGroup1 or a UserGroup2 object.
What I would suggest you do is make two seperate Models, that do not extend from the same Model (out of necessity): Group1 and Group2. You would store the information that is common to both profiles in the UserProfile of the User object. Then in the UserProfile you would have a ForeignKey to both a Group1 and a Group2 object:
group1 = models.ForeignKey(Group1, blank=True, null=True)
You would have to do the logic checking yourself, to ensure that only one is ever valid (you could just do this in an overridden save() method or something), but then to grab all of a user's data at once, and also know which group they are on you could do the following:
User.objects.filter(username='blahblah').select_related('profile', 'profile__group1', 'profile__group2')
Only one query to the database would give you all the information you'd need about a user, and you'd also know which group they are in (the one that isn't 'None').
I hope that helps.
P.S. I am assuming in this that groups don't just have unique data to each other, but also unique functionality.