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==============
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Custom lookups
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==============
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.. module:: django.db.models.lookups
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:synopsis: Custom lookups
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.. currentmodule:: django.db.models
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By default Django offers a wide variety of different lookups for filtering
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(for example, `exact` and `icontains`). This documentation explains how to
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write custom lookups and how to alter the working of existing lookups. In
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addition how to transform field values is explained. fFor example how to
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extract the year from a DateField. By writing a custom `YearExtract`
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transformer it is possible to filter on the transformed value, for example::
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Author.objects.filter(birthdate__year__lte=1981)
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Currently transformers are only available in filtering. So, it is not possible
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to use it in other parts of the ORM, for example this will not work::
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Author.objects.values_list('birthdate__year')
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A simple Lookup example
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~~~~~~~~~~~~~~~~~~~~~~~
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Lets start with a simple custom lookup. We will write a custom lookup `ne`
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which works opposite to `exact`. A `Author.objects.filter(name__ne='Jack')`
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will translate to::
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"author"."name" <> 'Jack'
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A custom lookup will need an implementation and Django needs to be told
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the existence of the lookup. The implementation for this lookup will be
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simple to write::
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from django.db.models import Lookup
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class NotEqual(Lookup):
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lookup_name = 'ne'
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def as_sql(self, qn, connection):
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lhs, lhs_params = self.process_lhs(qn, connection)
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rhs, rhs_params = self.process_rhs(qn, connection)
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params = lhs_params + rhs_params
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return '%s <> %s' % (lhs, rhs), params
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To register the `NotEqual` lookup we will just need to call register_lookup
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on the field class we want the lookup to be available::
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from django.db.models.fields import Field
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Field.register_lookup(NotEqual)
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Now Field and all its subclasses have a NotEqual lookup.
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The first notable thing about `NotEqual` is the lookup_name. This name must
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be supplied, and it is used by Django in the register_lookup() call so that
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Django knows to associate `ne` to the NotEqual implementation.
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`
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An Lookup works against two values, lhs and rhs. The abbreviations stand for
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left-hand side and right-hand side. The lhs is usually a field reference,
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but it can be anything implementing the query expression API. The
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rhs is the value given by the user. In the example `name__ne=Jack`, the
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lhs is reference to Author's name field and Jack is the value.
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The lhs and rhs are turned into values that are possible to use in SQL.
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In the example above lhs is turned into "author"."name", [], and rhs is
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turned into "%s", ['Jack']. The lhs is just raw string without parameters
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but the rhs is turned into a query parameter 'Jack'.
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Finally we combine the lhs and rhs by adding ` <> ` in between of them,
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and supply all the parameters for the query.
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A Lookup needs to implement a limited part of query expression API. See
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the query expression API for details.
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A simple transformer example
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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We will next write a simple transformer. The transformer will be called
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`YearExtract`. It can be used to extract the year part from `DateField`.
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Lets start by writing the implementation::
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from django.db.models import Extract
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class YearExtract(Extract):
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lookup_name = 'year'
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output_type = IntegerField()
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def as_sql(self, qn, connection):
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lhs, params = qn.compile(self.lhs)
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return "EXTRACT(YEAR FROM %s)" % lhs, params
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Next, lets register it for `DateField`::
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from django.db.models import DateField
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DateField.register_lookup(YearExtract)
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Now any DateField in your project will have `year` transformer. For example
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the following query::
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Author.objects.filter(birthdate__year__lte=1981)
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would translate to the following query on PostgreSQL::
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SELECT ...
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FROM "author"
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WHERE EXTRACT(YEAR FROM "author"."birthdate") <= 1981
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An YearExtract class works only against self.lhs. Usually the lhs is
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transformed in some way. Further lookups and extracts work against the
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transformed value.
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Note the definition of output_type in the `YearExtract`. The output_type is
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a field instance. It informs Django that the Extract class transformed the
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type of the value to an int. This is currently used only to check which
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lookups the extract has.
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The used SQL in this example works on most databases. Check you database
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vendor's documentation to see if EXTRACT(year from date) is supported.
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Writing an efficient year__exact lookup
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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When using the above written `year` lookup, the SQL produced will not use
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indexes efficiently. We will fix that by writing a custom `exact` lookup
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for YearExtract. For example if the user filters on
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`birthdate__year__exact=1981`, then we want to produce the following SQL::
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birthdate >= to_date('1981-01-01') AND birthdate <= to_date('1981-12-31')
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The implementation is::
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from django.db.models import Lookup
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class YearExact(Lookup):
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lookup_name = 'exact'
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def as_sql(self, qn, connection):
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lhs, lhs_params = qn.compile(self.lhs.lhs)
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rhs, rhs_params = self.process_rhs(qn, connection)
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params = lhs_params + rhs_params + lhs_params + rhs_params
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return '%s >= to_date(%s || '-01-01') AND %s <= to_date(%s || '-12-31') % (lhs, rhs, lhs, rhs), params
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YearExtract.register_lookup(YearExact)
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There are a couple of notable things going on. First, `YearExact` isn't
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calling process_lhs(). Instead it skips and compiles directly the lhs used by
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self.lhs. The reason this is done is to skip `YearExtract` from adding the
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EXTRACT clause to the query. Referring directly to self.lhs.lhs is safe as
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`YearExact` can be accessed only from `year__exact` lookup, that is the lhs
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is always `YearExtract`.
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Next, as both the lhs and rhs are used multiple times in the query the params
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need to contain lhs_params and rhs_params multiple times.
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The final query does string manipulation directly in the database. The reason
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for doing this is that if the self.rhs is something else than a plain integer
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value (for exampel a `F()` reference) we can't do the transformations in
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Python.
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Writing alternative implemenatations for existing lookups
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Sometimes different database vendors require different SQL for the same
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operation. For this example we will rewrite a custom implementation for
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MySQL for the NotEqual operator. Instead of `<>` we will be using `!=`
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operator.
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There are two ways to do this. The first is to write a subclass with a
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as_mysql() method and registering the subclass over the original class::
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class MySQLNotEqual(NotEqual):
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def as_mysql(self, qn, connection):
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lhs, lhs_params = self.process_lhs(qn, connection)
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rhs, rhs_params = self.process_rhs(qn, connection)
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params = lhs_params + rhs_params
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return '%s != %s' % (lhs, rhs), params
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Field.register_lookup(MySQLNotExact)
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The alternate is to monkey-patch the existing class in place::
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def as_mysql(self, qn, connection):
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lhs, lhs_params = self.process_lhs(qn, connection)
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rhs, rhs_params = self.process_rhs(qn, connection)
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params = lhs_params + rhs_params
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return '%s != %s' % (lhs, rhs), params
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NotEqual.as_mysql = as_mysql
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The subclass way allows one to override methods of the lookup if needed. The
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monkey-patch way allows writing different implementations for the same class
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in different locations of the project.
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The way Django knows to call as_mysql() instead of as_sql() is as follows.
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When qn.compile(notequal_instance) is called, Django first checks if there
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is a method named 'as_%s' % connection.vendor. If that method doesn't exist,
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the as_sql() will be called.
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The vendor names for Django's in-built backends are 'sqlite', 'postgresql',
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'oracle' and 'mysql'.
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The Lookup API
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~~~~~~~~~~~~~~
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An lookup has attributes lhs and rhs. The lhs is something implementing the
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query expression API and the rhs is either a plain value, or something that
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needs to be compiled into SQL. Examples of SQL-compiled values include `F()`
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references and usage of `QuerySets` as value.
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A lookup needs to define lookup_name as a class level attribute. This is used
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when registering lookups.
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A lookup has three public methods. The as_sql(qn, connection) method needs
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to produce a query string and parameters used by the query string. The qn has
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a method compile() which can be used to compile self.lhs. However usually it
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is better to call self.process_lhs(qn, connection) instead, which returns
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query string and parameters for the lhs. Similary process_rhs(qn, connection)
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returns query string and parameters for the rhs.
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The Query Expression API
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~~~~~~~~~~~~~~~~~~~~~~~~
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A lookup can assume that the lhs responds to the query expression API.
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Currently direct field references, aggregates and `Extract` instances respond
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to this API.
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.. method:: as_sql(qn, connection)
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Responsible for producing the query string and parameters for the expression.
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The qn has a compile() method that can be used to compile other expressions.
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The connection is the connection used to execute the query. The
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connection.vendor attribute can be used to return different query strings
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for different backends.
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Calling expression.as_sql() directly is usually an error - instead
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qn.compile(expression) should be used. The qn.compile() method will take
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care of calling vendor-specific methods of the expression.
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.. method:: as_vendorname(qn, connection)
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Works like as_sql() method. When an expression is compiled by qn.compile()
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Django will first try to call as_vendorname(), where vendorname is the vendor
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name of the backend used for executing the query. The vendorname is one of
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'postgresql', 'oracle', 'sqlite' or 'mysql' for Django's inbuilt backends.
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.. method:: get_lookup(lookup_name)::
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The get_lookup() method is used to fetch lookups. By default the lookup
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is fetched from the expression's output type, but it is possible to override
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this method to alter that behaviour.
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.. attribute:: output_type
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The output_type attribute is used by the get_lookup() method to check for
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lookups. The output_type should be a field instance.
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Note that this documentation lists only the public methods of the API.
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@ -1,241 +0,0 @@
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==============
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Custom lookups
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==============
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.. module:: django.db.models.lookups
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:synopsis: Custom lookups
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.. currentmodule:: django.db.models
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Django's ORM works using lookup paths when building query filters and other
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query conditions. For example in the query Book.filter(author__age__lte=30)
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the part "author__age__lte" is the lookup path.
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The lookup path consist of three different parts. First is the related
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lookups. In the author__age__lte example the part author refers to Book's
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related model Author. Second part of the lookup path is the field. This is
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Author's age field in the example. Finally the lte part is commonly called
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just lookup. Both the related lookups part and the final lookup part can
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contain multiple parts, for example "author__friends__birthdate__year__lte"
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has author, friends as related lookups, birthdate as the field and year, lte
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as final lookup part.
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This documentation concentrates on writing custom lookups. By writing custom
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lookups it is possible to control how Django interprets the final lookup part.
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Django will fetch a ``Lookup`` class from the final field using the field's
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method get_lookup(lookup_name). This method is allowed to do these things:
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1. Return a Lookup class
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2. Raise a FieldError
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3. Return None
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Returning None is only available during backwards compatibility period.
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The interpretation is to use the old way of lookup hadling inside the ORM.
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The Lookup class
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~~~~~~~~~~~~~~~~
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A Lookup operates on two values and produces boolean results. The values
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are called lhs and rhs. The lhs is usually a field reference, but it can be
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anything implementing the query expression API. The rhs is a value to compare
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against.
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The API is as follows:
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.. attribute:: lookup_name
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A string used by Django to distinguish different lookups. For example
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'exact'.
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.. method:: __init__(lhs, rhs)
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The lhs is something implementing the query expression API. For example in
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author__age__lte=30 the lhs is a Col instance referencing the age field of
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author model. The rhs is the value to compare against. It can be Python value
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(30 in the example) or SQL reference (produced by using F() or queryset for
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example).
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.. attribute:: Lookup.lhs
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The left hand side part of this lookup. You can assume it implements the
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query expression interface.
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.. attribute:: Lookup.rhs
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The value to compare against.
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.. method:: Lookup.process_lhs(qn, connection)
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Turns the lhs into query string + params.
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.. method:: Lookup.process_rhs(qn, connection)
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Turns the rhs into query string + params.
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.. method:: Lookup.as_sql(qn, connection)
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This method is used to produce the query string of the Lookup. A typical
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implementation is usually something like::
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def as_sql(self, qn, connection):
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lhs, params = self.process_lhs(qn, connection)
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rhs, rhs_params = self.process_rhs(qn, connection)
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params = lhs_params.extend(rhs_params)
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return '%s <OPERATOR> %s', (lhs, rhs), params
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where the <OPERATOR> is some query operator. The qn is a callable that
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can be used to convert strings to quoted variants (that is, colname to
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"colname"). Note that the quotation is *not* safe against SQL injection.
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In addition the qn implements method compile() which can be used to turn
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anything with as_sql() method to query string. You should always call
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qn.compile(part) instead of part.as_sql(qn, connection) so that 3rd party
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backends have ability to customize the produced query string. More of this
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later on.
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The connection is the connection the SQL is compiled against.
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In addition the Lookup class has some private methods - that is, implementing
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just the above mentioned attributes and methods is not enough, instead you
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must subclass Lookup.
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The Extract class
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~~~~~~~~~~~~~~~~~
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An Extract is something that converts a value to another value in the query
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string. For example you could have an Extract that procudes modulo 3 of the
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given value. In SQL this is something like "author"."age" % 3.
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Extracts are used in nested lookups. The Extract class must implement the
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query part interface.
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Extracts should be written by subclassing django.db.models.Extract.
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A simple Lookup example
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~~~~~~~~~~~~~~~~~~~~~~~
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This is how to write a simple mod3 lookup for IntegerField::
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from django.db.models import Lookup, IntegerField
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class Mod3(Lookup):
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lookup_name = 'mod3'
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def as_sql(self, qn, connection):
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lhs_sql, params = self.process_lhs(qn, connection)
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rhs_sql, rhs_params = self.process_rhs(qn, connection)
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params.extend(rhs_params)
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# We need doulbe-escaping for the %%%% operator.
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return '%s %%%% %s' % (lhs_sql, rhs_sql), params
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IntegerField.register_lookup(Div3)
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Now all IntegerFields or subclasses of IntegerField will have
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a mod3 lookup. For example you could do Author.objects.filter(age__mod3=2).
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This query would return every author whose age % 3 == 2.
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A simple nested lookup example
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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Here is how to write an Extract and a Lookup for IntegerField. The example
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lookup can be used similarly as the above mod3 lookup, and in addition it
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support nesting lookups::
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class Mod3Extract(Extract):
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lookup_name = 'mod3'
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def as_sql(self, qn, connection):
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lhs, lhs_params = qn.compile(self.lhs)
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return '%s %%%% 3' % (lhs,), lhs_params
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IntegerField.register_lookup(Mod3Extract)
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Note that if you already added Mod3 for IntegerField in the above
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example, now Mod3Extract will override that lookup.
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This lookup can be used like Mod3 lookup, but in addition it supports
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nesting, too. The default output type for Extracts is the same type as the
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lhs' output_type. So, the Mod3Extract supports all the same lookups as
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IntegerField. For example Author.objects.filter(age__mod3__in=[1, 2])
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returns all authors for which age % 3 in (1, 2).
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A more complex nested lookup
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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We will write a Year lookup that extracts year from date field. This
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field will convert the output type of the field - the lhs (or "input")
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field is DateField, but output is of type IntegerField.::
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from django.db.models import IntegerField, DateField
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from django.db.models.lookups import Extract
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class YearExtract(Extract):
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lookup_name = 'year'
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def as_sql(self, qn, connection):
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lhs_sql, params = qn.compile(self.lhs)
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# hmmh - this is internal API...
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return connection.ops.date_extract_sql('year', lhs_sql), params
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@property
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def output_type(self):
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return IntegerField()
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DateField.register_lookup(YearExtract)
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Now you could write Author.objects.filter(birthdate__year=1981). This will
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produce SQL like 'EXTRACT('year' from "author"."birthdate") = 1981'. The
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produces SQL depends on used backend. In addtition you can use any lookup
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defined for IntegerField, even div3 if you added that. So,
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Authos.objects.filter(birthdate__year__div3=2) will return every author
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with birthdate.year % 3 == 2.
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We could go further and add an optimized implementation for exact lookups::
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from django.db.models.lookups import Lookup
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class YearExtractOptimized(YearExtract):
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def get_lookup(self, lookup):
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if lookup == 'exact':
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return YearExact
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return super(YearExtractOptimized, self).get_lookup()
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class YearExact(Lookup):
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def as_sql(self, qn, connection):
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# We will need to skip the extract part, and instead go
|
||||
# directly with the originating field, that is self.lhs.lhs
|
||||
lhs_sql, lhs_params = self.process_lhs(qn, connection, self.lhs.lhs)
|
||||
rhs_sql, rhs_params = self.process_rhs(qn, connection)
|
||||
# Note that we must be careful so that we have params in the
|
||||
# same order as we have the parts in the SQL.
|
||||
params = []
|
||||
params.extend(lhs_params)
|
||||
params.extend(rhs_params)
|
||||
params.extend(lhs_params)
|
||||
params.extend(rhs_params)
|
||||
# We use PostgreSQL specific SQL here. Note that we must do the
|
||||
# conversions in SQL instead of in Python to support F() references.
|
||||
return ("%(lhs)s >= (%(rhs)s || '-01-01')::date "
|
||||
"AND %(lhs)s <= (%(rhs)s || '-12-31')::date" %
|
||||
{'lhs': lhs_sql, 'rhs': rhs_sql}, params)
|
||||
|
||||
Note that we used PostgreSQL specific SQL above. What if we want to support
|
||||
MySQL, too? This can be done by registering a different compiling implementation
|
||||
for MySQL::
|
||||
|
||||
from django.db.backends.utils import add_implementation
|
||||
@add_implementation(YearExact, 'mysql')
|
||||
def mysql_year_exact(node, qn, connection):
|
||||
lhs_sql, lhs_params = node.process_lhs(qn, connection, node.lhs.lhs)
|
||||
rhs_sql, rhs_params = node.process_rhs(qn, connection)
|
||||
params = []
|
||||
params.extend(lhs_params)
|
||||
params.extend(rhs_params)
|
||||
params.extend(lhs_params)
|
||||
params.extend(rhs_params)
|
||||
return ("%(lhs)s >= str_to_date(concat(%(rhs)s, '-01-01'), '%%%%Y-%%%%m-%%%%d') "
|
||||
"AND %(lhs)s <= str_to_date(concat(%(rhs)s, '-12-31'), '%%%%Y-%%%%m-%%%%d')" %
|
||||
{'lhs': lhs_sql, 'rhs': rhs_sql}, params)
|
||||
|
||||
Now, on MySQL instead of calling as_sql() of the YearExact Django will use the
|
||||
above compile implementation.
|
Loading…
Reference in New Issue