django/docs/ref/models/expressions.txt

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=================
Query Expressions
=================
.. currentmodule:: django.db.models
Query expressions describe a value or a computation that can be used as part of
an update, create, filter, order by, annotation, or aggregate. There are a
number of built-in expressions (documented below) that can be used to help you
write queries. Expressions can be combined, or in some cases nested, to form
more complex computations.
.. versionchanged:: 1.9
Support for using expressions when creating new model instances was added.
Supported arithmetic
====================
Django supports addition, subtraction, multiplication, division, modulo
arithmetic, and the power operator on query expressions, using Python constants,
variables, and even other expressions.
Some examples
=============
.. code-block:: python
from django.db.models import F, Count
from django.db.models.functions import Length, Upper, Value
# Find companies that have more employees than chairs.
Company.objects.filter(num_employees__gt=F('num_chairs'))
# Find companies that have at least twice as many employees
# as chairs. Both the querysets below are equivalent.
Company.objects.filter(num_employees__gt=F('num_chairs') * 2)
Company.objects.filter(
num_employees__gt=F('num_chairs') + F('num_chairs'))
# How many chairs are needed for each company to seat all employees?
>>> company = Company.objects.filter(
... num_employees__gt=F('num_chairs')).annotate(
... chairs_needed=F('num_employees') - F('num_chairs')).first()
>>> company.num_employees
120
>>> company.num_chairs
50
>>> company.chairs_needed
70
# Create a new company using expressions.
>>> company = Company.objects.create(name='Google', ticker=Upper(Value('goog')))
# Be sure to refresh it if you need to access the field.
>>> company.refresh_from_db()
>>> company.ticker
'GOOG'
# Annotate models with an aggregated value. Both forms
# below are equivalent.
Company.objects.annotate(num_products=Count('products'))
Company.objects.annotate(num_products=Count(F('products')))
# Aggregates can contain complex computations also
Company.objects.annotate(num_offerings=Count(F('products') + F('services')))
# Expressions can also be used in order_by()
Company.objects.order_by(Length('name').asc())
Company.objects.order_by(Length('name').desc())
Built-in Expressions
====================
.. note::
These expressions are defined in ``django.db.models.expressions`` and
``django.db.models.aggregates``, but for convenience they're available and
usually imported from :mod:`django.db.models`.
``F()`` expressions
-------------------
.. class:: F
An ``F()`` object represents the value of a model field or annotated column. It
makes it possible to refer to model field values and perform database
operations using them without actually having to pull them out of the database
into Python memory.
Instead, Django uses the ``F()`` object to generate a SQL expression that
describes the required operation at the database level.
This is easiest to understand through an example. Normally, one might do
something like this::
# Tintin filed a news story!
reporter = Reporters.objects.get(name='Tintin')
reporter.stories_filed += 1
reporter.save()
Here, we have pulled the value of ``reporter.stories_filed`` from the database
into memory and manipulated it using familiar Python operators, and then saved
the object back to the database. But instead we could also have done::
from django.db.models import F
reporter = Reporters.objects.get(name='Tintin')
reporter.stories_filed = F('stories_filed') + 1
reporter.save()
Although ``reporter.stories_filed = F('stories_filed') + 1`` looks like a
normal Python assignment of value to an instance attribute, in fact it's an SQL
construct describing an operation on the database.
When Django encounters an instance of ``F()``, it overrides the standard Python
operators to create an encapsulated SQL expression; in this case, one which
instructs the database to increment the database field represented by
``reporter.stories_filed``.
Whatever value is or was on ``reporter.stories_filed``, Python never gets to
know about it - it is dealt with entirely by the database. All Python does,
through Django's ``F()`` class, is create the SQL syntax to refer to the field
and describe the operation.
.. note::
In order to access the new value that has been saved in this way, the object
will need to be reloaded::
reporter = Reporters.objects.get(pk=reporter.pk)
# Or, more succinctly:
reporter.refresh_from_db()
As well as being used in operations on single instances as above, ``F()`` can
be used on ``QuerySets`` of object instances, with ``update()``. This reduces
the two queries we were using above - the ``get()`` and the
:meth:`~Model.save()` - to just one::
reporter = Reporters.objects.filter(name='Tintin')
reporter.update(stories_filed=F('stories_filed') + 1)
We can also use :meth:`~django.db.models.query.QuerySet.update()` to increment
the field value on multiple objects - which could be very much faster than
pulling them all into Python from the database, looping over them, incrementing
the field value of each one, and saving each one back to the database::
Reporter.objects.all().update(stories_filed=F('stories_filed') + 1)
``F()`` therefore can offer performance advantages by:
* getting the database, rather than Python, to do work
* reducing the number of queries some operations require
.. _avoiding-race-conditions-using-f:
Avoiding race conditions using ``F()``
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Another useful benefit of ``F()`` is that having the database - rather than
Python - update a field's value avoids a *race condition*.
If two Python threads execute the code in the first example above, one thread
could retrieve, increment, and save a field's value after the other has
retrieved it from the database. The value that the second thread saves will be
based on the original value; the work of the first thread will simply be lost.
If the database is responsible for updating the field, the process is more
robust: it will only ever update the field based on the value of the field in
the database when the :meth:`~Model.save()` or ``update()`` is executed, rather
than based on its value when the instance was retrieved.
Using ``F()`` in filters
~~~~~~~~~~~~~~~~~~~~~~~~
``F()`` is also very useful in ``QuerySet`` filters, where they make it
possible to filter a set of objects against criteria based on their field
values, rather than on Python values.
This is documented in :ref:`using F() expressions in queries
<using-f-expressions-in-filters>`.
.. _using-f-with-annotations:
Using ``F()`` with annotations
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
``F()`` can be used to create dynamic fields on your models by combining
different fields with arithmetic::
company = Company.objects.annotate(
chairs_needed=F('num_employees') - F('num_chairs'))
If the fields that you're combining are of different types you'll need
to tell Django what kind of field will be returned. Since ``F()`` does not
directly support ``output_field`` you will need to wrap the expression with
:class:`ExpressionWrapper`::
from django.db.models import DateTimeField, ExpressionWrapper, F
Ticket.objects.annotate(
expires=ExpressionWrapper(
F('active_at') + F('duration'), output_field=DateTimeField()))
.. _func-expressions:
``Func()`` expressions
----------------------
``Func()`` expressions are the base type of all expressions that involve
database functions like ``COALESCE`` and ``LOWER``, or aggregates like ``SUM``.
They can be used directly::
from django.db.models import Func, F
queryset.annotate(field_lower=Func(F('field'), function='LOWER'))
or they can be used to build a library of database functions::
class Lower(Func):
function = 'LOWER'
queryset.annotate(field_lower=Lower('field'))
But both cases will result in a queryset where each model is annotated with an
extra attribute ``field_lower`` produced, roughly, from the following SQL::
SELECT
...
LOWER("db_table"."field") as "field_lower"
See :doc:`database-functions` for a list of built-in database functions.
The ``Func`` API is as follows:
.. class:: Func(*expressions, **extra)
.. attribute:: function
A class attribute describing the function that will be generated.
Specifically, the ``function`` will be interpolated as the ``function``
placeholder within :attr:`template`. Defaults to ``None``.
.. attribute:: template
A class attribute, as a format string, that describes the SQL that is
generated for this function. Defaults to
``'%(function)s(%(expressions)s)'``.
.. attribute:: arg_joiner
A class attribute that denotes the character used to join the list of
``expressions`` together. Defaults to ``', '``.
.. attribute:: arity
.. versionadded:: 1.10
A class attribute that denotes the number of arguments the function
accepts. If this attribute is set and the function is called with a
different number of expressions, ``TypeError`` will be raised. Defaults
to ``None``.
The ``*expressions`` argument is a list of positional expressions that the
function will be applied to. The expressions will be converted to strings,
joined together with ``arg_joiner``, and then interpolated into the ``template``
as the ``expressions`` placeholder.
Positional arguments can be expressions or Python values. Strings are
assumed to be column references and will be wrapped in ``F()`` expressions
while other values will be wrapped in ``Value()`` expressions.
The ``**extra`` kwargs are ``key=value`` pairs that can be interpolated
into the ``template`` attribute. Note that the keywords ``function`` and
``template`` can be used to replace the ``function`` and ``template``
attributes respectively, without having to define your own class.
``output_field`` can be used to define the expected return type.
``Aggregate()`` expressions
---------------------------
An aggregate expression is a special case of a :ref:`Func() expression
<func-expressions>` that informs the query that a ``GROUP BY`` clause
is required. All of the :ref:`aggregate functions <aggregation-functions>`,
like ``Sum()`` and ``Count()``, inherit from ``Aggregate()``.
Since ``Aggregate``\s are expressions and wrap expressions, you can represent
some complex computations::
from django.db.models import Count
Company.objects.annotate(
managers_required=(Count('num_employees') / 4) + Count('num_managers'))
The ``Aggregate`` API is as follows:
.. class:: Aggregate(expression, output_field=None, **extra)
.. attribute:: template
A class attribute, as a format string, that describes the SQL that is
generated for this aggregate. Defaults to
``'%(function)s( %(expressions)s )'``.
.. attribute:: function
A class attribute describing the aggregate function that will be
generated. Specifically, the ``function`` will be interpolated as the
``function`` placeholder within :attr:`template`. Defaults to ``None``.
The ``expression`` argument can be the name of a field on the model, or another
expression. It will be converted to a string and used as the ``expressions``
placeholder within the ``template``.
The ``output_field`` argument requires a model field instance, like
``IntegerField()`` or ``BooleanField()``, into which Django will load the value
after it's retrieved from the database. Usually no arguments are needed when
instantiating the model field as any arguments relating to data validation
(``max_length``, ``max_digits``, etc.) will not be enforced on the expression's
output value.
Note that ``output_field`` is only required when Django is unable to determine
what field type the result should be. Complex expressions that mix field types
should define the desired ``output_field``. For example, adding an
``IntegerField()`` and a ``FloatField()`` together should probably have
``output_field=FloatField()`` defined.
The ``**extra`` kwargs are ``key=value`` pairs that can be interpolated
into the ``template`` attribute.
Creating your own Aggregate Functions
-------------------------------------
Creating your own aggregate is extremely easy. At a minimum, you need
to define ``function``, but you can also completely customize the
SQL that is generated. Here's a brief example::
from django.db.models import Aggregate
class Count(Aggregate):
# supports COUNT(distinct field)
function = 'COUNT'
template = '%(function)s(%(distinct)s%(expressions)s)'
def __init__(self, expression, distinct=False, **extra):
super(Count, self).__init__(
expression,
distinct='DISTINCT ' if distinct else '',
output_field=IntegerField(),
**extra)
``Value()`` expressions
-----------------------
.. class:: Value(value, output_field=None)
A ``Value()`` object represents the smallest possible component of an
expression: a simple value. When you need to represent the value of an integer,
boolean, or string within an expression, you can wrap that value within a
``Value()``.
You will rarely need to use ``Value()`` directly. When you write the expression
``F('field') + 1``, Django implicitly wraps the ``1`` in a ``Value()``,
allowing simple values to be used in more complex expressions. You will need to
use ``Value()`` when you want to pass a string to an expression. Most
expressions interpret a string argument as the name of a field, like
``Lower('name')``.
The ``value`` argument describes the value to be included in the expression,
such as ``1``, ``True``, or ``None``. Django knows how to convert these Python
values into their corresponding database type.
The ``output_field`` argument should be a model field instance, like
``IntegerField()`` or ``BooleanField()``, into which Django will load the value
after it's retrieved from the database. Usually no arguments are needed when
instantiating the model field as any arguments relating to data validation
(``max_length``, ``max_digits``, etc.) will not be enforced on the expression's
output value.
``ExpressionWrapper()`` expressions
-----------------------------------
.. class:: ExpressionWrapper(expression, output_field)
``ExpressionWrapper`` simply surrounds another expression and provides access
to properties, such as ``output_field``, that may not be available on other
expressions. ``ExpressionWrapper`` is necessary when using arithmetic on
``F()`` expressions with different types as described in
:ref:`using-f-with-annotations`.
Conditional expressions
-----------------------
Conditional expressions allow you to use :keyword:`if` ... :keyword:`elif` ...
:keyword:`else` logic in queries. Django natively supports SQL ``CASE``
expressions. For more details see :doc:`conditional-expressions`.
Raw SQL expressions
-------------------
.. currentmodule:: django.db.models.expressions
.. class:: RawSQL(sql, params, output_field=None)
Sometimes database expressions can't easily express a complex ``WHERE`` clause.
In these edge cases, use the ``RawSQL`` expression. For example::
>>> from django.db.models.expressions import RawSQL
>>> queryset.annotate(val=RawSQL("select col from sometable where othercol = %s", (someparam,)))
These extra lookups may not be portable to different database engines (because
you're explicitly writing SQL code) and violate the DRY principle, so you
should avoid them if possible.
.. warning::
You should be very careful to escape any parameters that the user can
control by using ``params`` in order to protect against :ref:`SQL injection
attacks <sql-injection-protection>`.
.. currentmodule:: django.db.models
Technical Information
=====================
Below you'll find technical implementation details that may be useful to
library authors. The technical API and examples below will help with
creating generic query expressions that can extend the built-in functionality
that Django provides.
Expression API
--------------
Query expressions implement the :ref:`query expression API <query-expression>`,
but also expose a number of extra methods and attributes listed below. All
query expressions must inherit from ``Expression()`` or a relevant
subclass.
When a query expression wraps another expression, it is responsible for
calling the appropriate methods on the wrapped expression.
.. class:: Expression
.. attribute:: contains_aggregate
Tells Django that this expression contains an aggregate and that a
``GROUP BY`` clause needs to be added to the query.
.. method:: resolve_expression(query=None, allow_joins=True, reuse=None, summarize=False)
Provides the chance to do any pre-processing or validation of
the expression before it's added to the query. ``resolve_expression()``
must also be called on any nested expressions. A ``copy()`` of ``self``
should be returned with any necessary transformations.
``query`` is the backend query implementation.
``allow_joins`` is a boolean that allows or denies the use of
joins in the query.
``reuse`` is a set of reusable joins for multi-join scenarios.
``summarize`` is a boolean that, when ``True``, signals that the
query being computed is a terminal aggregate query.
.. method:: get_source_expressions()
Returns an ordered list of inner expressions. For example::
>>> Sum(F('foo')).get_source_expressions()
[F('foo')]
.. method:: set_source_expressions(expressions)
Takes a list of expressions and stores them such that
``get_source_expressions()`` can return them.
.. method:: relabeled_clone(change_map)
Returns a clone (copy) of ``self``, with any column aliases relabeled.
Column aliases are renamed when subqueries are created.
``relabeled_clone()`` should also be called on any nested expressions
and assigned to the clone.
``change_map`` is a dictionary mapping old aliases to new aliases.
Example::
def relabeled_clone(self, change_map):
clone = copy.copy(self)
clone.expression = self.expression.relabeled_clone(change_map)
return clone
.. method:: convert_value(self, value, expression, connection, context)
A hook allowing the expression to coerce ``value`` into a more
appropriate type.
.. method:: refs_aggregate(existing_aggregates)
Returns a tuple containing the ``(aggregate, lookup_path)`` of the
first aggregate that this expression (or any nested expression)
references, or ``(False, ())`` if no aggregate is referenced.
For example::
queryset.filter(num_chairs__gt=F('sum__employees'))
The ``F()`` expression here references a previous ``Sum()``
computation which means that this filter expression should be
added to the ``HAVING`` clause rather than the ``WHERE`` clause.
In the majority of cases, returning the result of ``refs_aggregate``
on any nested expression should be appropriate, as the necessary
built-in expressions will return the correct values.
.. method:: get_group_by_cols()
Responsible for returning the list of columns references by
this expression. ``get_group_by_cols()`` should be called on any
nested expressions. ``F()`` objects, in particular, hold a reference
to a column.
.. method:: asc()
Returns the expression ready to be sorted in ascending order.
.. method:: desc()
Returns the expression ready to be sorted in descending order.
.. method:: reverse_ordering()
Returns ``self`` with any modifications required to reverse the sort
order within an ``order_by`` call. As an example, an expression
implementing ``NULLS LAST`` would change its value to be
``NULLS FIRST``. Modifications are only required for expressions that
implement sort order like ``OrderBy``. This method is called when
:meth:`~django.db.models.query.QuerySet.reverse()` is called on a
queryset.
Writing your own Query Expressions
----------------------------------
You can write your own query expression classes that use, and can integrate
with, other query expressions. Let's step through an example by writing an
implementation of the ``COALESCE`` SQL function, without using the built-in
:ref:`Func() expressions <func-expressions>`.
The ``COALESCE`` SQL function is defined as taking a list of columns or
values. It will return the first column or value that isn't ``NULL``.
We'll start by defining the template to be used for SQL generation and
an ``__init__()`` method to set some attributes::
import copy
from django.db.models import Expression
class Coalesce(Expression):
template = 'COALESCE( %(expressions)s )'
def __init__(self, expressions, output_field, **extra):
super(Coalesce, self).__init__(output_field=output_field)
if len(expressions) < 2:
raise ValueError('expressions must have at least 2 elements')
for expression in expressions:
if not hasattr(expression, 'resolve_expression'):
raise TypeError('%r is not an Expression' % expression)
self.expressions = expressions
self.extra = extra
We do some basic validation on the parameters, including requiring at least
2 columns or values, and ensuring they are expressions. We are requiring
``output_field`` here so that Django knows what kind of model field to assign
the eventual result to.
Now we implement the pre-processing and validation. Since we do not have
any of our own validation at this point, we just delegate to the nested
expressions::
def resolve_expression(self, query=None, allow_joins=True, reuse=None, summarize=False):
c = self.copy()
c.is_summary = summarize
for pos, expression in enumerate(self.expressions):
c.expressions[pos] = expression.resolve_expression(query, allow_joins, reuse, summarize)
return c
Next, we write the method responsible for generating the SQL::
def as_sql(self, compiler, connection):
sql_expressions, sql_params = [], []
for expression in self.expressions:
sql, params = compiler.compile(expression)
sql_expressions.append(sql)
sql_params.extend(params)
self.extra['expressions'] = ','.join(sql_expressions)
return self.template % self.extra, sql_params
def as_oracle(self, compiler, connection):
"""
Example of vendor specific handling (Oracle in this case).
Let's make the function name lowercase.
"""
self.template = 'coalesce( %(expressions)s )'
return self.as_sql(compiler, connection)
We generate the SQL for each of the ``expressions`` by using the
``compiler.compile()`` method, and join the result together with commas.
Then the template is filled out with our data and the SQL and parameters
are returned.
We've also defined a custom implementation that is specific to the Oracle
backend. The ``as_oracle()`` function will be called instead of ``as_sql()``
if the Oracle backend is in use.
Finally, we implement the rest of the methods that allow our query expression
to play nice with other query expressions::
def get_source_expressions(self):
return self.expressions
def set_source_expressions(self, expressions):
self.expressions = expressions
Let's see how it works::
>>> from django.db.models import F, Value, CharField
>>> qs = Company.objects.annotate(
... tagline=Coalesce([
... F('motto'),
... F('ticker_name'),
... F('description'),
... Value('No Tagline')
... ], output_field=CharField()))
>>> for c in qs:
... print("%s: %s" % (c.name, c.tagline))
...
Google: Do No Evil
Apple: AAPL
Yahoo: Internet Company
Django Software Foundation: No Tagline
Adding support in third-party database backends
-----------------------------------------------
If you're using a database backend that uses a different SQL syntax for a
certain function, you can add support for it by monkey patching a new method
onto the function's class.
Let's say we're writing a backend for Microsoft's SQL Server which uses the SQL
``LEN`` instead of ``LENGTH`` for the :class:`~functions.Length` function.
We'll monkey patch a new method called ``as_sqlserver()`` onto the ``Length``
class::
from django.db.models.functions import Length
def sqlserver_length(self, compiler, connection):
return self.as_sql(compiler, connection, function='LEN')
Length.as_sqlserver = sqlserver_length
You can also customize the SQL using the ``template`` parameter of ``as_sql()``.
We use ``as_sqlserver()`` because ``django.db.connection.vendor`` returns
``sqlserver`` for the backend.
Third-party backends can register their functions in the top level
``__init__.py`` file of the backend package or in a top level ``expressions.py``
file (or package) that is imported from the top level ``__init__.py``.
For user projects wishing to patch the backend that they're using, this code
should live in an :meth:`AppConfig.ready()<django.apps.AppConfig.ready>` method.