Migrations are Django’s way of propagating changes you make to your models (adding a field, deleting a model, etc.) into your database schema. They’re designed to be mostly automatic, but you’ll need to know when to make migrations, when to run them, and the common problems you might run into.
There are several commands which you will use to interact with migrations and Django’s handling of database schema:
migrate
, which is responsible for applying and unapplying
migrations.
makemigrations
, which is responsible for creating new migrations
based on the changes you have made to your models.
sqlmigrate
, which displays the SQL statements for a migration.
showmigrations
, which lists a project’s migrations and their
status.
You should think of migrations as a version control system for your database
schema. makemigrations
is responsible for packaging up your model changes
into individual migration files - analogous to commits - and migrate
is
responsible for applying those to your database.
The migration files for each app live in a “migrations” directory inside of that app, and are designed to be committed to, and distributed as part of, its codebase. You should be making them once on your development machine and then running the same migrations on your colleagues’ machines, your staging machines, and eventually your production machines.
Note
It is possible to override the name of the package which contains the
migrations on a per-app basis by modifying the MIGRATION_MODULES
setting.
Migrations will run the same way on the same dataset and produce consistent results, meaning that what you see in development and staging is, under the same circumstances, exactly what will happen in production.
Django will make migrations for any change to your models or fields - even options that don’t affect the database - as the only way it can reconstruct a field correctly is to have all the changes in the history, and you might need those options in some data migrations later on (for example, if you’ve set custom validators).
Migrations are supported on all backends that Django ships with, as well as any third-party backends if they have programmed in support for schema alteration (done via the SchemaEditor class).
However, some databases are more capable than others when it comes to schema migrations; some of the caveats are covered below.
PostgreSQL is the most capable of all the databases here in terms of schema support.
The only caveat is that prior to PostgreSQL 11, adding columns with default
values causes a full rewrite of the table, for a time proportional to its size.
For this reason, it’s recommended you always create new columns with
null=True
, as this way they will be added immediately.
MySQL lacks support for transactions around schema alteration operations, meaning that if a migration fails to apply you will have to manually unpick the changes in order to try again (it’s impossible to roll back to an earlier point).
In addition, MySQL will fully rewrite tables for almost every schema operation and generally takes a time proportional to the number of rows in the table to add or remove columns. On slower hardware this can be worse than a minute per million rows - adding a few columns to a table with just a few million rows could lock your site up for over ten minutes.
Finally, MySQL has relatively small limits on name lengths for columns, tables and indexes, as well as a limit on the combined size of all columns an index covers. This means that indexes that are possible on other backends will fail to be created under MySQL.
SQLite has very little built-in schema alteration support, and so Django attempts to emulate it by:
Creating a new table with the new schema
Copying the data across
Dropping the old table
Renaming the new table to match the original name
This process generally works well, but it can be slow and occasionally buggy. It is not recommended that you run and migrate SQLite in a production environment unless you are very aware of the risks and its limitations; the support Django ships with is designed to allow developers to use SQLite on their local machines to develop less complex Django projects without the need for a full database.
Django can create migrations for you. Make changes to your models - say, add a
field and remove a model - and then run makemigrations
:
$ python manage.py makemigrations
Migrations for 'books':
books/migrations/0003_auto.py:
- Alter field author on book
Your models will be scanned and compared to the versions currently
contained in your migration files, and then a new set of migrations
will be written out. Make sure to read the output to see what
makemigrations
thinks you have changed - it’s not perfect, and for
complex changes it might not be detecting what you expect.
Once you have your new migration files, you should apply them to your database to make sure they work as expected:
$ python manage.py migrate
Operations to perform:
Apply all migrations: books
Running migrations:
Rendering model states... DONE
Applying books.0003_auto... OK
Once the migration is applied, commit the migration and the models change to your version control system as a single commit - that way, when other developers (or your production servers) check out the code, they’ll get both the changes to your models and the accompanying migration at the same time.
If you want to give the migration(s) a meaningful name instead of a generated
one, you can use the makemigrations --name
option:
$ python manage.py makemigrations --name changed_my_model your_app_label
Because migrations are stored in version control, you’ll occasionally come across situations where you and another developer have both committed a migration to the same app at the same time, resulting in two migrations with the same number.
Don’t worry - the numbers are just there for developers’ reference, Django just cares that each migration has a different name. Migrations specify which other migrations they depend on - including earlier migrations in the same app - in the file, so it’s possible to detect when there’s two new migrations for the same app that aren’t ordered.
When this happens, Django will prompt you and give you some options. If it thinks it’s safe enough, it will offer to automatically linearize the two migrations for you. If not, you’ll have to go in and modify the migrations yourself - don’t worry, this isn’t difficult, and is explained more in Migration files below.
On databases that support DDL transactions (SQLite and PostgreSQL), all migration operations will run inside a single transaction by default. In contrast, if a database doesn’t support DDL transactions (e.g. MySQL, Oracle) then all operations will run without a transaction.
You can prevent a migration from running in a transaction by setting the
atomic
attribute to False
. For example:
from django.db import migrations
class Migration(migrations.Migration):
atomic = False
It’s also possible to execute parts of the migration inside a transaction using
atomic()
or by passing atomic=True
to
RunPython
. See
Non-atomic migrations for more details.
While migrations are per-app, the tables and relationships implied by
your models are too complex to be created for one app at a time. When you make
a migration that requires something else to run - for example, you add a
ForeignKey
in your books
app to your authors
app - the resulting
migration will contain a dependency on a migration in authors
.
This means that when you run the migrations, the authors
migration runs
first and creates the table the ForeignKey
references, and then the migration
that makes the ForeignKey
column runs afterwards and creates the constraint.
If this didn’t happen, the migration would try to create the ForeignKey
column without the table it’s referencing existing and your database would
throw an error.
This dependency behavior affects most migration operations where you
restrict to a single app. Restricting to a single app (either in
makemigrations
or migrate
) is a best-efforts promise, and not
a guarantee; any other apps that need to be used to get dependencies correct
will be.
Apps without migrations must not have relations (ForeignKey
,
ManyToManyField
, etc.) to apps with migrations. Sometimes it may work, but
it’s not supported.
Migrations are stored as an on-disk format, referred to here as “migration files”. These files are actually normal Python files with an agreed-upon object layout, written in a declarative style.
A basic migration file looks like this:
from django.db import migrations, models
class Migration(migrations.Migration):
dependencies = [('migrations', '0001_initial')]
operations = [
migrations.DeleteModel('Tribble'),
migrations.AddField('Author', 'rating', models.IntegerField(default=0)),
]
What Django looks for when it loads a migration file (as a Python module) is
a subclass of django.db.migrations.Migration
called Migration
. It then
inspects this object for four attributes, only two of which are used
most of the time:
dependencies
, a list of migrations this one depends on.
operations
, a list of Operation
classes that define what this
migration does.
The operations are the key; they are a set of declarative instructions which tell Django what schema changes need to be made. Django scans them and builds an in-memory representation of all of the schema changes to all apps, and uses this to generate the SQL which makes the schema changes.
That in-memory structure is also used to work out what the differences are
between your models and the current state of your migrations; Django runs
through all the changes, in order, on an in-memory set of models to come
up with the state of your models last time you ran makemigrations
. It
then uses these models to compare against the ones in your models.py
files
to work out what you have changed.
You should rarely, if ever, need to edit migration files by hand, but it’s entirely possible to write them manually if you need to. Some of the more complex operations are not autodetectable and are only available via a hand-written migration, so don’t be scared about editing them if you have to.
You can’t modify the number of positional arguments in an already migrated
custom field without raising a TypeError
. The old migration will call the
modified __init__
method with the old signature. So if you need a new
argument, please create a keyword argument and add something like
assert 'argument_name' in kwargs
in the constructor.
You can optionally serialize managers into migrations and have them available
in RunPython
operations. This is done
by defining a use_in_migrations
attribute on the manager class:
class MyManager(models.Manager):
use_in_migrations = True
class MyModel(models.Model):
objects = MyManager()
If you are using the from_queryset()
function to
dynamically generate a manager class, you need to inherit from the generated
class to make it importable:
class MyManager(MyBaseManager.from_queryset(CustomQuerySet)):
use_in_migrations = True
class MyModel(models.Model):
objects = MyManager()
Please refer to the notes about Historical models in migrations to see the implications that come along.
The “initial migrations” for an app are the migrations that create the first version of that app’s tables. Usually an app will have one initial migration, but in some cases of complex model interdependencies it may have two or more.
Initial migrations are marked with an initial = True
class attribute on the
migration class. If an initial
class attribute isn’t found, a migration
will be considered “initial” if it is the first migration in the app (i.e. if
it has no dependencies on any other migration in the same app).
When the migrate --fake-initial
option is used, these initial
migrations are treated specially. For an initial migration that creates one or
more tables (CreateModel
operation), Django checks that all of those tables
already exist in the database and fake-applies the migration if so. Similarly,
for an initial migration that adds one or more fields (AddField
operation),
Django checks that all of the respective columns already exist in the database
and fake-applies the migration if so. Without --fake-initial
, initial
migrations are treated no differently from any other migration.
As previously discussed, you may need to linearize migrations manually when two
development branches are joined. While editing migration dependencies, you can
inadvertently create an inconsistent history state where a migration has been
applied but some of its dependencies haven’t. This is a strong indication that
the dependencies are incorrect, so Django will refuse to run migrations or make
new migrations until it’s fixed. When using multiple databases, you can use the
allow_migrate()
method of database routers to control which databases
makemigrations
checks for consistent history.
New apps come preconfigured to accept migrations, and so you can add migrations
by running makemigrations
once you’ve made some changes.
If your app already has models and database tables, and doesn’t have migrations yet (for example, you created it against a previous Django version), you’ll need to convert it to use migrations by running:
$ python manage.py makemigrations your_app_label
This will make a new initial migration for your app. Now, run python
manage.py migrate --fake-initial
, and Django will detect that you have an
initial migration and that the tables it wants to create already exist, and
will mark the migration as already applied. (Without the migrate
--fake-initial
flag, the command would error out because the tables it wants
to create already exist.)
Note that this only works given two things:
You have not changed your models since you made their tables. For migrations to work, you must make the initial migration first and then make changes, as Django compares changes against migration files, not the database.
You have not manually edited your database - Django won’t be able to detect that your database doesn’t match your models, you’ll just get errors when migrations try to modify those tables.
Migrations can be reversed with migrate
by passing the number of the
previous migration. For example, to reverse migration books.0003
:
$ python manage.py migrate books 0002
Operations to perform:
Target specific migration: 0002_auto, from books
Running migrations:
Rendering model states... DONE
Unapplying books.0003_auto... OK
If you want to reverse all migrations applied for an app, use the name
zero
:
$ python manage.py migrate books zero
Operations to perform:
Unapply all migrations: books
Running migrations:
Rendering model states... DONE
Unapplying books.0002_auto... OK
Unapplying books.0001_initial... OK
A migration is irreversible if it contains any irreversible operations.
Attempting to reverse such migrations will raise IrreversibleError
:
$ python manage.py migrate books 0002
Operations to perform:
Target specific migration: 0002_auto, from books
Running migrations:
Rendering model states... DONE
Unapplying books.0003_auto...Traceback (most recent call last):
django.db.migrations.exceptions.IrreversibleError: Operation <RunSQL sql='DROP TABLE demo_books'> in books.0003_auto is not reversible
When you run migrations, Django is working from historical versions of your
models stored in the migration files. If you write Python code using the
RunPython
operation, or if you have
allow_migrate
methods on your database routers, you need to use these
historical model versions rather than importing them directly.
Warning
If you import models directly rather than using the historical models, your migrations may work initially but will fail in the future when you try to re-run old migrations (commonly, when you set up a new installation and run through all the migrations to set up the database).
This means that historical model problems may not be immediately obvious. If you run into this kind of failure, it’s OK to edit the migration to use the historical models rather than direct imports and commit those changes.
Because it’s impossible to serialize arbitrary Python code, these historical
models will not have any custom methods that you have defined. They will,
however, have the same fields, relationships, managers (limited to those with
use_in_migrations = True
) and Meta
options (also versioned, so they may
be different from your current ones).
Warning
This means that you will NOT have custom save()
methods called on objects
when you access them in migrations, and you will NOT have any custom
constructors or instance methods. Plan appropriately!
References to functions in field options such as upload_to
and
limit_choices_to
and model manager declarations with managers having
use_in_migrations = True
are serialized in migrations, so the functions and
classes will need to be kept around for as long as there is a migration
referencing them. Any custom model fields
will also need to be kept, since these are imported directly by migrations.
In addition, the concrete base classes of the model are stored as pointers, so you must always keep base classes around for as long as there is a migration that contains a reference to them. On the plus side, methods and managers from these base classes inherit normally, so if you absolutely need access to these you can opt to move them into a superclass.
To remove old references, you can squash migrations or, if there aren’t many references, copy them into the migration files.
Similar to the “references to historical functions” considerations described in the previous section, removing custom model fields from your project or third-party app will cause a problem if they are referenced in old migrations.
To help with this situation, Django provides some model field attributes to assist with model field deprecation using the system checks framework.
Add the system_check_deprecated_details
attribute to your model field
similar to the following:
class IPAddressField(Field):
system_check_deprecated_details = {
'msg': (
'IPAddressField has been deprecated. Support for it (except '
'in historical migrations) will be removed in Django 1.9.'
),
'hint': 'Use GenericIPAddressField instead.', # optional
'id': 'fields.W900', # pick a unique ID for your field.
}
After a deprecation period of your choosing (two or three feature releases for
fields in Django itself), change the system_check_deprecated_details
attribute to system_check_removed_details
and update the dictionary similar
to:
class IPAddressField(Field):
system_check_removed_details = {
'msg': (
'IPAddressField has been removed except for support in '
'historical migrations.'
),
'hint': 'Use GenericIPAddressField instead.',
'id': 'fields.E900', # pick a unique ID for your field.
}
You should keep the field’s methods that are required for it to operate in
database migrations such as __init__()
, deconstruct()
, and
get_internal_type()
. Keep this stub field for as long as any migrations
which reference the field exist. For example, after squashing migrations and
removing the old ones, you should be able to remove the field completely.
As well as changing the database schema, you can also use migrations to change the data in the database itself, in conjunction with the schema if you want.
Migrations that alter data are usually called “data migrations”; they’re best written as separate migrations, sitting alongside your schema migrations.
Django can’t automatically generate data migrations for you, as it does with
schema migrations, but it’s not very hard to write them. Migration files in
Django are made up of Operations, and
the main operation you use for data migrations is
RunPython
.
To start, make an empty migration file you can work from (Django will put the file in the right place, suggest a name, and add dependencies for you):
python manage.py makemigrations --empty yourappname
Then, open up the file; it should look something like this:
# Generated by Django A.B on YYYY-MM-DD HH:MM
from django.db import migrations
class Migration(migrations.Migration):
dependencies = [
('yourappname', '0001_initial'),
]
operations = [
]
Now, all you need to do is create a new function and have
RunPython
use it.
RunPython
expects a callable as its argument
which takes two arguments - the first is an app registry that has the historical versions of all your models
loaded into it to match where in your history the migration sits, and the
second is a SchemaEditor, which you can use to
manually effect database schema changes (but beware, doing this can confuse
the migration autodetector!)
Let’s write a migration that populates our new name
field with the combined
values of first_name
and last_name
(we’ve come to our senses and
realized that not everyone has first and last names). All we need to do is use
the historical model and iterate over the rows:
from django.db import migrations
def combine_names(apps, schema_editor):
# We can't import the Person model directly as it may be a newer
# version than this migration expects. We use the historical version.
Person = apps.get_model('yourappname', 'Person')
for person in Person.objects.all():
person.name = '%s %s' % (person.first_name, person.last_name)
person.save()
class Migration(migrations.Migration):
dependencies = [
('yourappname', '0001_initial'),
]
operations = [
migrations.RunPython(combine_names),
]
Once that’s done, we can run python manage.py migrate
as normal and the
data migration will run in place alongside other migrations.
You can pass a second callable to
RunPython
to run whatever logic you
want executed when migrating backwards. If this callable is omitted, migrating
backwards will raise an exception.
When writing a RunPython
function that uses models from apps other than the
one in which the migration is located, the migration’s dependencies
attribute should include the latest migration of each app that is involved,
otherwise you may get an error similar to: LookupError: No installed app
with label 'myappname'
when you try to retrieve the model in the RunPython
function using apps.get_model()
.
In the following example, we have a migration in app1
which needs to use
models in app2
. We aren’t concerned with the details of move_m1
other
than the fact it will need to access models from both apps. Therefore we’ve
added a dependency that specifies the last migration of app2
:
class Migration(migrations.Migration):
dependencies = [
('app1', '0001_initial'),
# added dependency to enable using models from app2 in move_m1
('app2', '0004_foobar'),
]
operations = [
migrations.RunPython(move_m1),
]
If you’re interested in the more advanced migration operations, or want to be able to write your own, see the migration operations reference and the “how-to” on writing migrations.
You are encouraged to make migrations freely and not worry about how many you have; the migration code is optimized to deal with hundreds at a time without much slowdown. However, eventually you will want to move back from having several hundred migrations to just a few, and that’s where squashing comes in.
Squashing is the act of reducing an existing set of many migrations down to one (or sometimes a few) migrations which still represent the same changes.
Django does this by taking all of your existing migrations, extracting their
Operation
s and putting them all in sequence, and then running an optimizer
over them to try and reduce the length of the list - for example, it knows
that CreateModel
and
DeleteModel
cancel each other out,
and it knows that AddField
can be
rolled into CreateModel
.
Once the operation sequence has been reduced as much as possible - the amount
possible depends on how closely intertwined your models are and if you have
any RunSQL
or RunPython
operations (which can’t
be optimized through unless they are marked as elidable
) - Django will then
write it back out into a new set of migration files.
These files are marked to say they replace the previously-squashed migrations, so they can coexist with the old migration files, and Django will intelligently switch between them depending where you are in the history. If you’re still part-way through the set of migrations that you squashed, it will keep using them until it hits the end and then switch to the squashed history, while new installs will use the new squashed migration and skip all the old ones.
This enables you to squash and not mess up systems currently in production that aren’t fully up-to-date yet. The recommended process is to squash, keeping the old files, commit and release, wait until all systems are upgraded with the new release (or if you’re a third-party project, ensure your users upgrade releases in order without skipping any), and then remove the old files, commit and do a second release.
The command that backs all this is squashmigrations
- pass it the
app label and migration name you want to squash up to, and it’ll get to work:
$ ./manage.py squashmigrations myapp 0004
Will squash the following migrations:
- 0001_initial
- 0002_some_change
- 0003_another_change
- 0004_undo_something
Do you wish to proceed? [yN] y
Optimizing...
Optimized from 12 operations to 7 operations.
Created new squashed migration /home/andrew/Programs/DjangoTest/test/migrations/0001_squashed_0004_undo_somthing.py
You should commit this migration but leave the old ones in place;
the new migration will be used for new installs. Once you are sure
all instances of the codebase have applied the migrations you squashed,
you can delete them.
Use the squashmigrations --squashed-name
option if you want to set
the name of the squashed migration rather than use an autogenerated one.
Note that model interdependencies in Django can get very complex, and squashing
may result in migrations that do not run; either mis-optimized (in which case
you can try again with --no-optimize
, though you should also report an issue),
or with a CircularDependencyError
, in which case you can manually resolve it.
To manually resolve a CircularDependencyError
, break out one of
the ForeignKeys in the circular dependency loop into a separate
migration, and move the dependency on the other app with it. If you’re unsure,
see how makemigrations
deals with the problem when asked to create
brand new migrations from your models. In a future release of Django,
squashmigrations
will be updated to attempt to resolve these errors
itself.
Once you’ve squashed your migration, you should then commit it alongside the
migrations it replaces and distribute this change to all running instances
of your application, making sure that they run migrate
to store the change
in their database.
You must then transition the squashed migration to a normal migration by:
Deleting all the migration files it replaces.
Updating all migrations that depend on the deleted migrations to depend on the squashed migration instead.
Removing the replaces
attribute in the Migration
class of the
squashed migration (this is how Django tells that it is a squashed migration).
Note
Once you’ve squashed a migration, you should not then re-squash that squashed migration until you have fully transitioned it to a normal migration.
Migrations are Python files containing the old definitions of your models - thus, to write them, Django must take the current state of your models and serialize them out into a file.
While Django can serialize most things, there are some things that we just
can’t serialize out into a valid Python representation - there’s no Python
standard for how a value can be turned back into code (repr()
only works
for basic values, and doesn’t specify import paths).
Django can serialize the following:
int
, float
, bool
, str
, bytes
, None
, NoneType
list
, set
, tuple
, dict
, range
.
datetime.date
, datetime.time
, and datetime.datetime
instances
(include those that are timezone-aware)
decimal.Decimal
instances
enum.Enum
instances
uuid.UUID
instances
functools.partial()
and functools.partialmethod
instances
which have serializable func
, args
, and keywords
values.
Pure and concrete path objects from pathlib
. Concrete paths are
converted to their pure path equivalent, e.g. pathlib.PosixPath
to
pathlib.PurePosixPath
.
os.PathLike
instances, e.g. os.DirEntry
, which are
converted to str
or bytes
using os.fspath()
.
LazyObject
instances which wrap a serializable value.
Enumeration types (e.g. TextChoices
or IntegerChoices
) instances.
Any Django field
Any function or method reference (e.g. datetime.datetime.today
) (must be in module’s top-level scope)
Unbound methods used from within the class body
Any class reference (must be in module’s top-level scope)
Anything with a custom deconstruct()
method (see below)
Serialization support for pure and concrete path objects from
pathlib
, and os.PathLike
instances was added.
Django cannot serialize:
Nested classes
Arbitrary class instances (e.g. MyClass(4.3, 5.7)
)
Lambdas
You can serialize other types by writing a custom serializer. For example, if
Django didn’t serialize Decimal
by default, you could do
this:
from decimal import Decimal
from django.db.migrations.serializer import BaseSerializer
from django.db.migrations.writer import MigrationWriter
class DecimalSerializer(BaseSerializer):
def serialize(self):
return repr(self.value), {'from decimal import Decimal'}
MigrationWriter.register_serializer(Decimal, DecimalSerializer)
The first argument of MigrationWriter.register_serializer()
is a type or
iterable of types that should use the serializer.
The serialize()
method of your serializer must return a string of how the
value should appear in migrations and a set of any imports that are needed in
the migration.
deconstruct()
method¶You can let Django serialize your own custom class instances by giving the class
a deconstruct()
method. It takes no arguments, and should return a tuple
of three things (path, args, kwargs)
:
path
should be the Python path to the class, with the class name included
as the last part (for example, myapp.custom_things.MyClass
). If your
class is not available at the top level of a module it is not serializable.
args
should be a list of positional arguments to pass to your class’
__init__
method. Everything in this list should itself be serializable.
kwargs
should be a dict of keyword arguments to pass to your class’
__init__
method. Every value should itself be serializable.
Note
This return value is different from the deconstruct()
method
for custom fields which returns a
tuple of four items.
Django will write out the value as an instantiation of your class with the given arguments, similar to the way it writes out references to Django fields.
To prevent a new migration from being created each time
makemigrations
is run, you should also add a __eq__()
method to
the decorated class. This function will be called by Django’s migration
framework to detect changes between states.
As long as all of the arguments to your class’ constructor are themselves
serializable, you can use the @deconstructible
class decorator from
django.utils.deconstruct
to add the deconstruct()
method:
from django.utils.deconstruct import deconstructible
@deconstructible
class MyCustomClass:
def __init__(self, foo=1):
self.foo = foo
...
def __eq__(self, other):
return self.foo == other.foo
The decorator adds logic to capture and preserve the arguments on their way into your constructor, and then returns those arguments exactly when deconstruct() is called.
If you are the maintainer of a third-party app with models, you may need to
ship migrations that support multiple Django versions. In this case, you should
always run makemigrations
with the lowest Django version you wish
to support.
The migrations system will maintain backwards-compatibility according to the same policy as the rest of Django, so migration files generated on Django X.Y should run unchanged on Django X.Y+1. The migrations system does not promise forwards-compatibility, however. New features may be added, and migration files generated with newer versions of Django may not work on older versions.
See also
Covers the schema operations API, special operations, and writing your own operations.
Explains how to structure and write database migrations for different scenarios you might encounter.
Dec 25, 2023