Database Functions
The classes documented below provide a way for users to use functions provided by the underlying database as annotations, aggregations, or filters in Django. Functions are also expressions, so they can be used and combined with other expressions like aggregate functions.
We’ll be using the following model in examples of each function:
class Author(models.Model):
name = models.CharField(max_length=50)
age = models.PositiveIntegerField(null=True, blank=True)
alias = models.CharField(max_length=50, null=True, blank=True)
goes_by = models.CharField(max_length=50, null=True, blank=True)
We don’t usually recommend allowing null=True
for CharField
since this allows the field to have two “empty values”, but it’s important for the Coalesce
example below.
Comparison and conversion functions
Cast
class Cast
(expression, output_field)[source]
Forces the result type of expression
to be the one from output_field
.
Usage example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import Cast
>>> Author.objects.create(age=25, name="Margaret Smith")
>>> author = Author.objects.annotate(
... age_as_float=Cast("age", output_field=FloatField()),
... ).get()
>>> print(author.age_as_float)
25.0
Coalesce
class Coalesce
(*expressions, **extra)[source]
Accepts a list of at least two field names or expressions and returns the first non-null value (note that an empty string is not considered a null value). Each argument must be of a similar type, so mixing text and numbers will result in a database error.
Usage examples:
>>> # Get a screen name from least to most public
>>> from django.db.models import Sum
>>> from django.db.models.functions import Coalesce
>>> Author.objects.create(name="Margaret Smith", goes_by="Maggie")
>>> author = Author.objects.annotate(screen_name=Coalesce("alias", "goes_by", "name")).get()
>>> print(author.screen_name)
Maggie
>>> # Prevent an aggregate Sum() from returning None
>>> # The aggregate default argument uses Coalesce() under the hood.
>>> aggregated = Author.objects.aggregate(
... combined_age=Sum("age"),
... combined_age_default=Sum("age", default=0),
... combined_age_coalesce=Coalesce(Sum("age"), 0),
... )
>>> print(aggregated["combined_age"])
None
>>> print(aggregated["combined_age_default"])
0
>>> print(aggregated["combined_age_coalesce"])
0
Warning
A Python value passed to Coalesce
on MySQL may be converted to an incorrect type unless explicitly cast to the correct database type:
>>> from django.db.models import DateTimeField
>>> from django.db.models.functions import Cast, Coalesce
>>> from django.utils import timezone
>>> now = timezone.now()
>>> Coalesce("updated", Cast(now, DateTimeField()))
Collate
class Collate
(expression, collation)[source]
Takes an expression and a collation name to query against.
For example, to filter case-insensitively in SQLite:
>>> Author.objects.filter(name=Collate(Value("john"), "nocase"))
<QuerySet [<Author: John>, <Author: john>]>
It can also be used when ordering, for example with PostgreSQL:
>>> Author.objects.order_by(Collate("name", "et-x-icu"))
<QuerySet [<Author: Ursula>, <Author: Veronika>, <Author: Ülle>]>
Greatest
class Greatest
(*expressions, **extra)[source]
Accepts a list of at least two field names or expressions and returns the greatest value. Each argument must be of a similar type, so mixing text and numbers will result in a database error.
Usage example:
class Blog(models.Model):
body = models.TextField()
modified = models.DateTimeField(auto_now=True)
class Comment(models.Model):
body = models.TextField()
modified = models.DateTimeField(auto_now=True)
blog = models.ForeignKey(Blog, on_delete=models.CASCADE)
>>> from django.db.models.functions import Greatest
>>> blog = Blog.objects.create(body="Greatest is the best.")
>>> comment = Comment.objects.create(body="No, Least is better.", blog=blog)
>>> comments = Comment.objects.annotate(last_updated=Greatest("modified", "blog__modified"))
>>> annotated_comment = comments.get()
annotated_comment.last_updated
will be the most recent of blog.modified
and comment.modified
.
Warning
The behavior of Greatest
when one or more expression may be null
varies between databases:
- PostgreSQL:
Greatest
will return the largest non-null expression, ornull
if all expressions arenull
. - SQLite, Oracle, and MySQL: If any expression is
null
,Greatest
will returnnull
.
The PostgreSQL behavior can be emulated using Coalesce
if you know a sensible minimum value to provide as a default.
JSONObject
class JSONObject
(**fields)[source]
Takes a list of key-value pairs and returns a JSON object containing those pairs.
Usage example:
>>> from django.db.models import F
>>> from django.db.models.functions import JSONObject, Lower
>>> Author.objects.create(name="Margaret Smith", alias="msmith", age=25)
>>> author = Author.objects.annotate(
... json_object=JSONObject(
... name=Lower("name"),
... alias="alias",
... age=F("age") * 2,
... )
... ).get()
>>> author.json_object
{'name': 'margaret smith', 'alias': 'msmith', 'age': 50}
Least
class Least
(*expressions, **extra)[source]
Accepts a list of at least two field names or expressions and returns the least value. Each argument must be of a similar type, so mixing text and numbers will result in a database error.
Warning
The behavior of Least
when one or more expression may be null
varies between databases:
- PostgreSQL:
Least
will return the smallest non-null expression, ornull
if all expressions arenull
. - SQLite, Oracle, and MySQL: If any expression is
null
,Least
will returnnull
.
The PostgreSQL behavior can be emulated using Coalesce
if you know a sensible maximum value to provide as a default.
NullIf
class NullIf
(expression1, expression2)[source]
Accepts two expressions and returns None
if they are equal, otherwise returns expression1
.
Caveats on Oracle
Due to an Oracle convention, this function returns the empty string instead of None
when the expressions are of type CharField.
Passing Value(None)
to expression1
is prohibited on Oracle since Oracle doesn’t accept NULL
as the first argument.
Date functions
We’ll be using the following model in examples of each function:
class Experiment(models.Model):
start_datetime = models.DateTimeField()
start_date = models.DateField(null=True, blank=True)
start_time = models.TimeField(null=True, blank=True)
end_datetime = models.DateTimeField(null=True, blank=True)
end_date = models.DateField(null=True, blank=True)
end_time = models.TimeField(null=True, blank=True)
Extract
class Extract
(expression, lookup_name=None, tzinfo=None, **extra)[source]
Extracts a component of a date as a number.
Takes an expression
representing a DateField
, DateTimeField
, TimeField
, or DurationField
and a lookup_name
, and returns the part of the date referenced by lookup_name
as an IntegerField
. Django usually uses the databases’ extract function, so you may use any lookup_name
that your database supports. A tzinfo
subclass, usually provided by zoneinfo, can be passed to extract a value in a specific timezone.
Given the datetime 2015-06-15 23:30:01.000321+00:00
, the built-in lookup_name
s return:
- “year”: 2015
- “iso_year”: 2015
- “quarter”: 2
- “month”: 6
- “day”: 15
- “week”: 25
- “week_day”: 2
- “iso_week_day”: 1
- “hour”: 23
- “minute”: 30
- “second”: 1
If a different timezone like Australia/Melbourne
is active in Django, then the datetime is converted to the timezone before the value is extracted. The timezone offset for Melbourne in the example date above is +10:00. The values returned when this timezone is active will be the same as above except for:
- “day”: 16
- “week_day”: 3
- “iso_week_day”: 2
- “hour”: 9
week_day
values
The week_day
lookup_type
is calculated differently from most databases and from Python’s standard functions. This function will return 1
for Sunday, 2
for Monday, through 7
for Saturday.
The equivalent calculation in Python is:
>>> from datetime import datetime
>>> dt = datetime(2015, 6, 15)
>>> (dt.isoweekday() % 7) + 1
2
week
values
The week
lookup_type
is calculated based on ISO-8601, i.e., a week starts on a Monday. The first week of a year is the one that contains the year’s first Thursday, i.e. the first week has the majority (four or more) of its days in the year. The value returned is in the range 1 to 52 or 53.
Each lookup_name
above has a corresponding Extract
subclass (listed below) that should typically be used instead of the more verbose equivalent, e.g. use ExtractYear(...)
rather than Extract(..., lookup_name='year')
.
Usage example:
>>> from datetime import datetime
>>> from django.db.models.functions import Extract
>>> start = datetime(2015, 6, 15)
>>> end = datetime(2015, 7, 2)
>>> Experiment.objects.create(
... start_datetime=start, start_date=start.date(), end_datetime=end, end_date=end.date()
... )
>>> # Add the experiment start year as a field in the QuerySet.
>>> experiment = Experiment.objects.annotate(
... start_year=Extract("start_datetime", "year")
... ).get()
>>> experiment.start_year
2015
>>> # How many experiments completed in the same year in which they started?
>>> Experiment.objects.filter(start_datetime__year=Extract("end_datetime", "year")).count()
1
DateField
extracts
class ExtractYear
(expression, tzinfo=None, **extra)[source]
lookup_name = 'year'
class ExtractIsoYear
(expression, tzinfo=None, **extra)[source]
Returns the ISO-8601 week-numbering year.
lookup_name = 'iso_year'
class ExtractMonth
(expression, tzinfo=None, **extra)[source]
lookup_name = 'month'
class ExtractDay
(expression, tzinfo=None, **extra)[source]
lookup_name = 'day'
class ExtractWeekDay
(expression, tzinfo=None, **extra)[source]
lookup_name = 'week_day'
class ExtractIsoWeekDay
(expression, tzinfo=None, **extra)[source]
Returns the ISO-8601 week day with day 1 being Monday and day 7 being Sunday.
lookup_name = 'iso_week_day'
class ExtractWeek
(expression, tzinfo=None, **extra)[source]
lookup_name = 'week'
class ExtractQuarter
(expression, tzinfo=None, **extra)[source]
lookup_name = 'quarter'
These are logically equivalent to Extract('date_field', lookup_name)
. Each class is also a Transform
registered on DateField
and DateTimeField
as __(lookup_name)
, e.g. __year
.
Since DateField
s don’t have a time component, only Extract
subclasses that deal with date-parts can be used with DateField
:
>>> from datetime import datetime, timezone
>>> from django.db.models.functions import (
... ExtractDay,
... ExtractMonth,
... ExtractQuarter,
... ExtractWeek,
... ExtractIsoWeekDay,
... ExtractWeekDay,
... ExtractIsoYear,
... ExtractYear,
... )
>>> start_2015 = datetime(2015, 6, 15, 23, 30, 1, tzinfo=timezone.utc)
>>> end_2015 = datetime(2015, 6, 16, 13, 11, 27, tzinfo=timezone.utc)
>>> Experiment.objects.create(
... start_datetime=start_2015,
... start_date=start_2015.date(),
... end_datetime=end_2015,
... end_date=end_2015.date(),
... )
>>> Experiment.objects.annotate(
... year=ExtractYear("start_date"),
... isoyear=ExtractIsoYear("start_date"),
... quarter=ExtractQuarter("start_date"),
... month=ExtractMonth("start_date"),
... week=ExtractWeek("start_date"),
... day=ExtractDay("start_date"),
... weekday=ExtractWeekDay("start_date"),
... isoweekday=ExtractIsoWeekDay("start_date"),
... ).values(
... "year",
... "isoyear",
... "quarter",
... "month",
... "week",
... "day",
... "weekday",
... "isoweekday",
... ).get(
... end_date__year=ExtractYear("start_date")
... )
{'year': 2015, 'isoyear': 2015, 'quarter': 2, 'month': 6, 'week': 25,
'day': 15, 'weekday': 2, 'isoweekday': 1}
DateTimeField
extracts
In addition to the following, all extracts for DateField
listed above may also be used on DateTimeField
s .
class ExtractHour
(expression, tzinfo=None, **extra)[source]
lookup_name = 'hour'
class ExtractMinute
(expression, tzinfo=None, **extra)[source]
lookup_name = 'minute'
class ExtractSecond
(expression, tzinfo=None, **extra)[source]
lookup_name = 'second'
These are logically equivalent to Extract('datetime_field', lookup_name)
. Each class is also a Transform
registered on DateTimeField
as __(lookup_name)
, e.g. __minute
.
DateTimeField
examples:
>>> from datetime import datetime, timezone
>>> from django.db.models.functions import (
... ExtractDay,
... ExtractHour,
... ExtractMinute,
... ExtractMonth,
... ExtractQuarter,
... ExtractSecond,
... ExtractWeek,
... ExtractIsoWeekDay,
... ExtractWeekDay,
... ExtractIsoYear,
... ExtractYear,
... )
>>> start_2015 = datetime(2015, 6, 15, 23, 30, 1, tzinfo=timezone.utc)
>>> end_2015 = datetime(2015, 6, 16, 13, 11, 27, tzinfo=timezone.utc)
>>> Experiment.objects.create(
... start_datetime=start_2015,
... start_date=start_2015.date(),
... end_datetime=end_2015,
... end_date=end_2015.date(),
... )
>>> Experiment.objects.annotate(
... year=ExtractYear("start_datetime"),
... isoyear=ExtractIsoYear("start_datetime"),
... quarter=ExtractQuarter("start_datetime"),
... month=ExtractMonth("start_datetime"),
... week=ExtractWeek("start_datetime"),
... day=ExtractDay("start_datetime"),
... weekday=ExtractWeekDay("start_datetime"),
... isoweekday=ExtractIsoWeekDay("start_datetime"),
... hour=ExtractHour("start_datetime"),
... minute=ExtractMinute("start_datetime"),
... second=ExtractSecond("start_datetime"),
... ).values(
... "year",
... "isoyear",
... "month",
... "week",
... "day",
... "weekday",
... "isoweekday",
... "hour",
... "minute",
... "second",
... ).get(
... end_datetime__year=ExtractYear("start_datetime")
... )
{'year': 2015, 'isoyear': 2015, 'quarter': 2, 'month': 6, 'week': 25,
'day': 15, 'weekday': 2, 'isoweekday': 1, 'hour': 23, 'minute': 30,
'second': 1}
When USE_TZ is True
then datetimes are stored in the database in UTC. If a different timezone is active in Django, the datetime is converted to that timezone before the value is extracted. The example below converts to the Melbourne timezone (UTC +10:00), which changes the day, weekday, and hour values that are returned:
>>> from django.utils import timezone
>>> import zoneinfo
>>> melb = zoneinfo.ZoneInfo("Australia/Melbourne") # UTC+10:00
>>> with timezone.override(melb):
... Experiment.objects.annotate(
... day=ExtractDay("start_datetime"),
... weekday=ExtractWeekDay("start_datetime"),
... isoweekday=ExtractIsoWeekDay("start_datetime"),
... hour=ExtractHour("start_datetime"),
... ).values("day", "weekday", "isoweekday", "hour").get(
... end_datetime__year=ExtractYear("start_datetime"),
... )
...
{'day': 16, 'weekday': 3, 'isoweekday': 2, 'hour': 9}
Explicitly passing the timezone to the Extract
function behaves in the same way, and takes priority over an active timezone:
>>> import zoneinfo
>>> melb = zoneinfo.ZoneInfo("Australia/Melbourne")
>>> Experiment.objects.annotate(
... day=ExtractDay("start_datetime", tzinfo=melb),
... weekday=ExtractWeekDay("start_datetime", tzinfo=melb),
... isoweekday=ExtractIsoWeekDay("start_datetime", tzinfo=melb),
... hour=ExtractHour("start_datetime", tzinfo=melb),
... ).values("day", "weekday", "isoweekday", "hour").get(
... end_datetime__year=ExtractYear("start_datetime"),
... )
{'day': 16, 'weekday': 3, 'isoweekday': 2, 'hour': 9}
Now
class Now
[source]
Returns the database server’s current date and time when the query is executed, typically using the SQL CURRENT_TIMESTAMP
.
Usage example:
>>> from django.db.models.functions import Now
>>> Article.objects.filter(published__lte=Now())
<QuerySet [<Article: How to Django>]>
PostgreSQL considerations
On PostgreSQL, the SQL CURRENT_TIMESTAMP
returns the time that the current transaction started. Therefore for cross-database compatibility, Now()
uses STATEMENT_TIMESTAMP
instead. If you need the transaction timestamp, use django.contrib.postgres.functions.TransactionNow.
Oracle
On Oracle, the SQL LOCALTIMESTAMP
is used to avoid issues with casting CURRENT_TIMESTAMP
to DateTimeField
.
Changed in Django 5.0:
In older versions, the SQL CURRENT_TIMESTAMP
was used on Oracle instead of LOCALTIMESTAMP
.
Trunc
class Trunc
(expression, kind, output_field=None, tzinfo=None, **extra)[source]
Truncates a date up to a significant component.
When you only care if something happened in a particular year, hour, or day, but not the exact second, then Trunc
(and its subclasses) can be useful to filter or aggregate your data. For example, you can use Trunc
to calculate the number of sales per day.
Trunc
takes a single expression
, representing a DateField
, TimeField
, or DateTimeField
, a kind
representing a date or time part, and an output_field
that’s either DateTimeField()
, TimeField()
, or DateField()
. It returns a datetime, date, or time depending on output_field
, with fields up to kind
set to their minimum value. If output_field
is omitted, it will default to the output_field
of expression
. A tzinfo
subclass, usually provided by zoneinfo, can be passed to truncate a value in a specific timezone.
Given the datetime 2015-06-15 14:30:50.000321+00:00
, the built-in kind
s return:
- “year”: 2015-01-01 00:00:00+00:00
- “quarter”: 2015-04-01 00:00:00+00:00
- “month”: 2015-06-01 00:00:00+00:00
- “week”: 2015-06-15 00:00:00+00:00
- “day”: 2015-06-15 00:00:00+00:00
- “hour”: 2015-06-15 14:00:00+00:00
- “minute”: 2015-06-15 14:30:00+00:00
- “second”: 2015-06-15 14:30:50+00:00
If a different timezone like Australia/Melbourne
is active in Django, then the datetime is converted to the new timezone before the value is truncated. The timezone offset for Melbourne in the example date above is +10:00. The values returned when this timezone is active will be:
- “year”: 2015-01-01 00:00:00+11:00
- “quarter”: 2015-04-01 00:00:00+10:00
- “month”: 2015-06-01 00:00:00+10:00
- “week”: 2015-06-16 00:00:00+10:00
- “day”: 2015-06-16 00:00:00+10:00
- “hour”: 2015-06-16 00:00:00+10:00
- “minute”: 2015-06-16 00:30:00+10:00
- “second”: 2015-06-16 00:30:50+10:00
The year has an offset of +11:00 because the result transitioned into daylight saving time.
Each kind
above has a corresponding Trunc
subclass (listed below) that should typically be used instead of the more verbose equivalent, e.g. use TruncYear(...)
rather than Trunc(..., kind='year')
.
The subclasses are all defined as transforms, but they aren’t registered with any fields, because the lookup names are already reserved by the Extract
subclasses.
Usage example:
>>> from datetime import datetime
>>> from django.db.models import Count, DateTimeField
>>> from django.db.models.functions import Trunc
>>> Experiment.objects.create(start_datetime=datetime(2015, 6, 15, 14, 30, 50, 321))
>>> Experiment.objects.create(start_datetime=datetime(2015, 6, 15, 14, 40, 2, 123))
>>> Experiment.objects.create(start_datetime=datetime(2015, 12, 25, 10, 5, 27, 999))
>>> experiments_per_day = (
... Experiment.objects.annotate(
... start_day=Trunc("start_datetime", "day", output_field=DateTimeField())
... )
... .values("start_day")
... .annotate(experiments=Count("id"))
... )
>>> for exp in experiments_per_day:
... print(exp["start_day"], exp["experiments"])
...
2015-06-15 00:00:00 2
2015-12-25 00:00:00 1
>>> experiments = Experiment.objects.annotate(
... start_day=Trunc("start_datetime", "day", output_field=DateTimeField())
... ).filter(start_day=datetime(2015, 6, 15))
>>> for exp in experiments:
... print(exp.start_datetime)
...
2015-06-15 14:30:50.000321
2015-06-15 14:40:02.000123
DateField
truncation
class TruncYear
(expression, output_field=None, tzinfo=None, **extra)[source]
kind = 'year'
class TruncMonth
(expression, output_field=None, tzinfo=None, **extra)[source]
kind = 'month'
class TruncWeek
(expression, output_field=None, tzinfo=None, **extra)[source]
Truncates to midnight on the Monday of the week.
kind = 'week'
class TruncQuarter
(expression, output_field=None, tzinfo=None, **extra)[source]
kind = 'quarter'
These are logically equivalent to Trunc('date_field', kind)
. They truncate all parts of the date up to kind
which allows grouping or filtering dates with less precision. expression
can have an output_field
of either DateField
or DateTimeField
.
Since DateField
s don’t have a time component, only Trunc
subclasses that deal with date-parts can be used with DateField
:
>>> from datetime import datetime, timezone
>>> from django.db.models import Count
>>> from django.db.models.functions import TruncMonth, TruncYear
>>> start1 = datetime(2014, 6, 15, 14, 30, 50, 321, tzinfo=timezone.utc)
>>> start2 = datetime(2015, 6, 15, 14, 40, 2, 123, tzinfo=timezone.utc)
>>> start3 = datetime(2015, 12, 31, 17, 5, 27, 999, tzinfo=timezone.utc)
>>> Experiment.objects.create(start_datetime=start1, start_date=start1.date())
>>> Experiment.objects.create(start_datetime=start2, start_date=start2.date())
>>> Experiment.objects.create(start_datetime=start3, start_date=start3.date())
>>> experiments_per_year = (
... Experiment.objects.annotate(year=TruncYear("start_date"))
... .values("year")
... .annotate(experiments=Count("id"))
... )
>>> for exp in experiments_per_year:
... print(exp["year"], exp["experiments"])
...
2014-01-01 1
2015-01-01 2
>>> import zoneinfo
>>> melb = zoneinfo.ZoneInfo("Australia/Melbourne")
>>> experiments_per_month = (
... Experiment.objects.annotate(month=TruncMonth("start_datetime", tzinfo=melb))
... .values("month")
... .annotate(experiments=Count("id"))
... )
>>> for exp in experiments_per_month:
... print(exp["month"], exp["experiments"])
...
2015-06-01 00:00:00+10:00 1
2016-01-01 00:00:00+11:00 1
2014-06-01 00:00:00+10:00 1
DateTimeField
truncation
class TruncDate
(expression, tzinfo=None, **extra)[source]
lookup_name = 'date'
output_field = DateField()
TruncDate
casts expression
to a date rather than using the built-in SQL truncate function. It’s also registered as a transform on DateTimeField
as __date
.
class TruncTime
(expression, tzinfo=None, **extra)[source]
lookup_name = 'time'
output_field = TimeField()
TruncTime
casts expression
to a time rather than using the built-in SQL truncate function. It’s also registered as a transform on DateTimeField
as __time
.
class TruncDay
(expression, output_field=None, tzinfo=None, **extra)[source]
kind = 'day'
class TruncHour
(expression, output_field=None, tzinfo=None, **extra)[source]
kind = 'hour'
class TruncMinute
(expression, output_field=None, tzinfo=None, **extra)[source]
kind = 'minute'
class TruncSecond
(expression, output_field=None, tzinfo=None, **extra)[source]
kind = 'second'
These are logically equivalent to Trunc('datetime_field', kind)
. They truncate all parts of the date up to kind
and allow grouping or filtering datetimes with less precision. expression
must have an output_field
of DateTimeField
.
Usage example:
>>> from datetime import date, datetime, timezone
>>> from django.db.models import Count
>>> from django.db.models.functions import (
... TruncDate,
... TruncDay,
... TruncHour,
... TruncMinute,
... TruncSecond,
... )
>>> import zoneinfo
>>> start1 = datetime(2014, 6, 15, 14, 30, 50, 321, tzinfo=timezone.utc)
>>> Experiment.objects.create(start_datetime=start1, start_date=start1.date())
>>> melb = zoneinfo.ZoneInfo("Australia/Melbourne")
>>> Experiment.objects.annotate(
... date=TruncDate("start_datetime"),
... day=TruncDay("start_datetime", tzinfo=melb),
... hour=TruncHour("start_datetime", tzinfo=melb),
... minute=TruncMinute("start_datetime"),
... second=TruncSecond("start_datetime"),
... ).values("date", "day", "hour", "minute", "second").get()
{'date': datetime.date(2014, 6, 15),
'day': datetime.datetime(2014, 6, 16, 0, 0, tzinfo=zoneinfo.ZoneInfo('Australia/Melbourne')),
'hour': datetime.datetime(2014, 6, 16, 0, 0, tzinfo=zoneinfo.ZoneInfo('Australia/Melbourne')),
'minute': 'minute': datetime.datetime(2014, 6, 15, 14, 30, tzinfo=timezone.utc),
'second': datetime.datetime(2014, 6, 15, 14, 30, 50, tzinfo=timezone.utc)
}
TimeField
truncation
class TruncHour
(expression, output_field=None, tzinfo=None, **extra)[source]
kind = 'hour'
class TruncMinute
(expression, output_field=None, tzinfo=None, **extra)[source]
kind = 'minute'
class TruncSecond
(expression, output_field=None, tzinfo=None, **extra)[source]
kind = 'second'
These are logically equivalent to Trunc('time_field', kind)
. They truncate all parts of the time up to kind
which allows grouping or filtering times with less precision. expression
can have an output_field
of either TimeField
or DateTimeField
.
Since TimeField
s don’t have a date component, only Trunc
subclasses that deal with time-parts can be used with TimeField
:
>>> from datetime import datetime, timezone
>>> from django.db.models import Count, TimeField
>>> from django.db.models.functions import TruncHour
>>> start1 = datetime(2014, 6, 15, 14, 30, 50, 321, tzinfo=timezone.utc)
>>> start2 = datetime(2014, 6, 15, 14, 40, 2, 123, tzinfo=timezone.utc)
>>> start3 = datetime(2015, 12, 31, 17, 5, 27, 999, tzinfo=timezone.utc)
>>> Experiment.objects.create(start_datetime=start1, start_time=start1.time())
>>> Experiment.objects.create(start_datetime=start2, start_time=start2.time())
>>> Experiment.objects.create(start_datetime=start3, start_time=start3.time())
>>> experiments_per_hour = (
... Experiment.objects.annotate(
... hour=TruncHour("start_datetime", output_field=TimeField()),
... )
... .values("hour")
... .annotate(experiments=Count("id"))
... )
>>> for exp in experiments_per_hour:
... print(exp["hour"], exp["experiments"])
...
14:00:00 2
17:00:00 1
>>> import zoneinfo
>>> melb = zoneinfo.ZoneInfo("Australia/Melbourne")
>>> experiments_per_hour = (
... Experiment.objects.annotate(
... hour=TruncHour("start_datetime", tzinfo=melb),
... )
... .values("hour")
... .annotate(experiments=Count("id"))
... )
>>> for exp in experiments_per_hour:
... print(exp["hour"], exp["experiments"])
...
2014-06-16 00:00:00+10:00 2
2016-01-01 04:00:00+11:00 1
Math Functions
We’ll be using the following model in math function examples:
class Vector(models.Model):
x = models.FloatField()
y = models.FloatField()
Abs
class Abs
(expression, **extra)[source]
Returns the absolute value of a numeric field or expression.
Usage example:
>>> from django.db.models.functions import Abs
>>> Vector.objects.create(x=-0.5, y=1.1)
>>> vector = Vector.objects.annotate(x_abs=Abs("x"), y_abs=Abs("y")).get()
>>> vector.x_abs, vector.y_abs
(0.5, 1.1)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import Abs
>>> FloatField.register_lookup(Abs)
>>> # Get vectors inside the unit cube
>>> vectors = Vector.objects.filter(x__abs__lt=1, y__abs__lt=1)
ACos
class ACos
(expression, **extra)[source]
Returns the arccosine of a numeric field or expression. The expression value must be within the range -1 to 1.
Usage example:
>>> from django.db.models.functions import ACos
>>> Vector.objects.create(x=0.5, y=-0.9)
>>> vector = Vector.objects.annotate(x_acos=ACos("x"), y_acos=ACos("y")).get()
>>> vector.x_acos, vector.y_acos
(1.0471975511965979, 2.6905658417935308)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import ACos
>>> FloatField.register_lookup(ACos)
>>> # Get vectors whose arccosine is less than 1
>>> vectors = Vector.objects.filter(x__acos__lt=1, y__acos__lt=1)
ASin
class ASin
(expression, **extra)[source]
Returns the arcsine of a numeric field or expression. The expression value must be in the range -1 to 1.
Usage example:
>>> from django.db.models.functions import ASin
>>> Vector.objects.create(x=0, y=1)
>>> vector = Vector.objects.annotate(x_asin=ASin("x"), y_asin=ASin("y")).get()
>>> vector.x_asin, vector.y_asin
(0.0, 1.5707963267948966)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import ASin
>>> FloatField.register_lookup(ASin)
>>> # Get vectors whose arcsine is less than 1
>>> vectors = Vector.objects.filter(x__asin__lt=1, y__asin__lt=1)
ATan
class ATan
(expression, **extra)[source]
Returns the arctangent of a numeric field or expression.
Usage example:
>>> from django.db.models.functions import ATan
>>> Vector.objects.create(x=3.12, y=6.987)
>>> vector = Vector.objects.annotate(x_atan=ATan("x"), y_atan=ATan("y")).get()
>>> vector.x_atan, vector.y_atan
(1.2606282660069106, 1.428638798133829)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import ATan
>>> FloatField.register_lookup(ATan)
>>> # Get vectors whose arctangent is less than 2
>>> vectors = Vector.objects.filter(x__atan__lt=2, y__atan__lt=2)
ATan2
class ATan2
(expression1, expression2, **extra)[source]
Returns the arctangent of expression1 / expression2
.
Usage example:
>>> from django.db.models.functions import ATan2
>>> Vector.objects.create(x=2.5, y=1.9)
>>> vector = Vector.objects.annotate(atan2=ATan2("x", "y")).get()
>>> vector.atan2
0.9209258773829491
Ceil
class Ceil
(expression, **extra)[source]
Returns the smallest integer greater than or equal to a numeric field or expression.
Usage example:
>>> from django.db.models.functions import Ceil
>>> Vector.objects.create(x=3.12, y=7.0)
>>> vector = Vector.objects.annotate(x_ceil=Ceil("x"), y_ceil=Ceil("y")).get()
>>> vector.x_ceil, vector.y_ceil
(4.0, 7.0)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import Ceil
>>> FloatField.register_lookup(Ceil)
>>> # Get vectors whose ceil is less than 10
>>> vectors = Vector.objects.filter(x__ceil__lt=10, y__ceil__lt=10)
Cos
class Cos
(expression, **extra)[source]
Returns the cosine of a numeric field or expression.
Usage example:
>>> from django.db.models.functions import Cos
>>> Vector.objects.create(x=-8.0, y=3.1415926)
>>> vector = Vector.objects.annotate(x_cos=Cos("x"), y_cos=Cos("y")).get()
>>> vector.x_cos, vector.y_cos
(-0.14550003380861354, -0.9999999999999986)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import Cos
>>> FloatField.register_lookup(Cos)
>>> # Get vectors whose cosine is less than 0.5
>>> vectors = Vector.objects.filter(x__cos__lt=0.5, y__cos__lt=0.5)
Cot
class Cot
(expression, **extra)[source]
Returns the cotangent of a numeric field or expression.
Usage example:
>>> from django.db.models.functions import Cot
>>> Vector.objects.create(x=12.0, y=1.0)
>>> vector = Vector.objects.annotate(x_cot=Cot("x"), y_cot=Cot("y")).get()
>>> vector.x_cot, vector.y_cot
(-1.5726734063976826, 0.642092615934331)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import Cot
>>> FloatField.register_lookup(Cot)
>>> # Get vectors whose cotangent is less than 1
>>> vectors = Vector.objects.filter(x__cot__lt=1, y__cot__lt=1)
Degrees
class Degrees
(expression, **extra)[source]
Converts a numeric field or expression from radians to degrees.
Usage example:
>>> from django.db.models.functions import Degrees
>>> Vector.objects.create(x=-1.57, y=3.14)
>>> vector = Vector.objects.annotate(x_d=Degrees("x"), y_d=Degrees("y")).get()
>>> vector.x_d, vector.y_d
(-89.95437383553924, 179.9087476710785)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import Degrees
>>> FloatField.register_lookup(Degrees)
>>> # Get vectors whose degrees are less than 360
>>> vectors = Vector.objects.filter(x__degrees__lt=360, y__degrees__lt=360)
Exp
class Exp
(expression, **extra)[source]
Returns the value of e
(the natural logarithm base) raised to the power of a numeric field or expression.
Usage example:
>>> from django.db.models.functions import Exp
>>> Vector.objects.create(x=5.4, y=-2.0)
>>> vector = Vector.objects.annotate(x_exp=Exp("x"), y_exp=Exp("y")).get()
>>> vector.x_exp, vector.y_exp
(221.40641620418717, 0.1353352832366127)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import Exp
>>> FloatField.register_lookup(Exp)
>>> # Get vectors whose exp() is greater than 10
>>> vectors = Vector.objects.filter(x__exp__gt=10, y__exp__gt=10)
Floor
class Floor
(expression, **extra)[source]
Returns the largest integer value not greater than a numeric field or expression.
Usage example:
>>> from django.db.models.functions import Floor
>>> Vector.objects.create(x=5.4, y=-2.3)
>>> vector = Vector.objects.annotate(x_floor=Floor("x"), y_floor=Floor("y")).get()
>>> vector.x_floor, vector.y_floor
(5.0, -3.0)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import Floor
>>> FloatField.register_lookup(Floor)
>>> # Get vectors whose floor() is greater than 10
>>> vectors = Vector.objects.filter(x__floor__gt=10, y__floor__gt=10)
Ln
class Ln
(expression, **extra)[source]
Returns the natural logarithm a numeric field or expression.
Usage example:
>>> from django.db.models.functions import Ln
>>> Vector.objects.create(x=5.4, y=233.0)
>>> vector = Vector.objects.annotate(x_ln=Ln("x"), y_ln=Ln("y")).get()
>>> vector.x_ln, vector.y_ln
(1.6863989535702288, 5.4510384535657)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import Ln
>>> FloatField.register_lookup(Ln)
>>> # Get vectors whose value greater than e
>>> vectors = Vector.objects.filter(x__ln__gt=1, y__ln__gt=1)
Log
class Log
(expression1, expression2, **extra)[source]
Accepts two numeric fields or expressions and returns the logarithm of the second to base of the first.
Usage example:
>>> from django.db.models.functions import Log
>>> Vector.objects.create(x=2.0, y=4.0)
>>> vector = Vector.objects.annotate(log=Log("x", "y")).get()
>>> vector.log
2.0
Mod
class Mod
(expression1, expression2, **extra)[source]
Accepts two numeric fields or expressions and returns the remainder of the first divided by the second (modulo operation).
Usage example:
>>> from django.db.models.functions import Mod
>>> Vector.objects.create(x=5.4, y=2.3)
>>> vector = Vector.objects.annotate(mod=Mod("x", "y")).get()
>>> vector.mod
0.8
Pi
class Pi
(**extra)[source]
Returns the value of the mathematical constant π
.
Power
class Power
(expression1, expression2, **extra)[source]
Accepts two numeric fields or expressions and returns the value of the first raised to the power of the second.
Usage example:
>>> from django.db.models.functions import Power
>>> Vector.objects.create(x=2, y=-2)
>>> vector = Vector.objects.annotate(power=Power("x", "y")).get()
>>> vector.power
0.25
Radians
class Radians
(expression, **extra)[source]
Converts a numeric field or expression from degrees to radians.
Usage example:
>>> from django.db.models.functions import Radians
>>> Vector.objects.create(x=-90, y=180)
>>> vector = Vector.objects.annotate(x_r=Radians("x"), y_r=Radians("y")).get()
>>> vector.x_r, vector.y_r
(-1.5707963267948966, 3.141592653589793)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import Radians
>>> FloatField.register_lookup(Radians)
>>> # Get vectors whose radians are less than 1
>>> vectors = Vector.objects.filter(x__radians__lt=1, y__radians__lt=1)
Random
class Random
(**extra)[source]
Returns a random value in the range 0.0 ≤ x < 1.0
.
Round
class Round
(expression, precision=0, **extra)[source]
Rounds a numeric field or expression to precision
(must be an integer) decimal places. By default, it rounds to the nearest integer. Whether half values are rounded up or down depends on the database.
Usage example:
>>> from django.db.models.functions import Round
>>> Vector.objects.create(x=5.4, y=-2.37)
>>> vector = Vector.objects.annotate(x_r=Round("x"), y_r=Round("y", precision=1)).get()
>>> vector.x_r, vector.y_r
(5.0, -2.4)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import Round
>>> FloatField.register_lookup(Round)
>>> # Get vectors whose round() is less than 20
>>> vectors = Vector.objects.filter(x__round__lt=20, y__round__lt=20)
Sign
class Sign
(expression, **extra)[source]
Returns the sign (-1, 0, 1) of a numeric field or expression.
Usage example:
>>> from django.db.models.functions import Sign
>>> Vector.objects.create(x=5.4, y=-2.3)
>>> vector = Vector.objects.annotate(x_sign=Sign("x"), y_sign=Sign("y")).get()
>>> vector.x_sign, vector.y_sign
(1, -1)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import Sign
>>> FloatField.register_lookup(Sign)
>>> # Get vectors whose signs of components are less than 0.
>>> vectors = Vector.objects.filter(x__sign__lt=0, y__sign__lt=0)
Sin
class Sin
(expression, **extra)[source]
Returns the sine of a numeric field or expression.
Usage example:
>>> from django.db.models.functions import Sin
>>> Vector.objects.create(x=5.4, y=-2.3)
>>> vector = Vector.objects.annotate(x_sin=Sin("x"), y_sin=Sin("y")).get()
>>> vector.x_sin, vector.y_sin
(-0.7727644875559871, -0.7457052121767203)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import Sin
>>> FloatField.register_lookup(Sin)
>>> # Get vectors whose sin() is less than 0
>>> vectors = Vector.objects.filter(x__sin__lt=0, y__sin__lt=0)
Sqrt
class Sqrt
(expression, **extra)[source]
Returns the square root of a nonnegative numeric field or expression.
Usage example:
>>> from django.db.models.functions import Sqrt
>>> Vector.objects.create(x=4.0, y=12.0)
>>> vector = Vector.objects.annotate(x_sqrt=Sqrt("x"), y_sqrt=Sqrt("y")).get()
>>> vector.x_sqrt, vector.y_sqrt
(2.0, 3.46410)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import Sqrt
>>> FloatField.register_lookup(Sqrt)
>>> # Get vectors whose sqrt() is less than 5
>>> vectors = Vector.objects.filter(x__sqrt__lt=5, y__sqrt__lt=5)
Tan
class Tan
(expression, **extra)[source]
Returns the tangent of a numeric field or expression.
Usage example:
>>> from django.db.models.functions import Tan
>>> Vector.objects.create(x=0, y=12)
>>> vector = Vector.objects.annotate(x_tan=Tan("x"), y_tan=Tan("y")).get()
>>> vector.x_tan, vector.y_tan
(0.0, -0.6358599286615808)
It can also be registered as a transform. For example:
>>> from django.db.models import FloatField
>>> from django.db.models.functions import Tan
>>> FloatField.register_lookup(Tan)
>>> # Get vectors whose tangent is less than 0
>>> vectors = Vector.objects.filter(x__tan__lt=0, y__tan__lt=0)
Text functions
Chr
class Chr
(expression, **extra)[source]
Accepts a numeric field or expression and returns the text representation of the expression as a single character. It works the same as Python’s chr() function.
Like Length, it can be registered as a transform on IntegerField
. The default lookup name is chr
.
Usage example:
>>> from django.db.models.functions import Chr
>>> Author.objects.create(name="Margaret Smith")
>>> author = Author.objects.filter(name__startswith=Chr(ord("M"))).get()
>>> print(author.name)
Margaret Smith
Concat
class Concat
(*expressions, **extra)[source]
Accepts a list of at least two text fields or expressions and returns the concatenated text. Each argument must be of a text or char type. If you want to concatenate a TextField()
with a CharField()
, then be sure to tell Django that the output_field
should be a TextField()
. Specifying an output_field
is also required when concatenating a Value
as in the example below.
This function will never have a null result. On backends where a null argument results in the entire expression being null, Django will ensure that each null part is converted to an empty string first.
Usage example:
>>> # Get the display name as "name (goes_by)"
>>> from django.db.models import CharField, Value as V
>>> from django.db.models.functions import Concat
>>> Author.objects.create(name="Margaret Smith", goes_by="Maggie")
>>> author = Author.objects.annotate(
... screen_name=Concat("name", V(" ("), "goes_by", V(")"), output_field=CharField())
... ).get()
>>> print(author.screen_name)
Margaret Smith (Maggie)
Left
class Left
(expression, length, **extra)[source]
Returns the first length
characters of the given text field or expression.
Usage example:
>>> from django.db.models.functions import Left
>>> Author.objects.create(name="Margaret Smith")
>>> author = Author.objects.annotate(first_initial=Left("name", 1)).get()
>>> print(author.first_initial)
M
Length
class Length
(expression, **extra)[source]
Accepts a single text field or expression and returns the number of characters the value has. If the expression is null, then the length will also be null.
Usage example:
>>> # Get the length of the name and goes_by fields
>>> from django.db.models.functions import Length
>>> Author.objects.create(name="Margaret Smith")
>>> author = Author.objects.annotate(
... name_length=Length("name"), goes_by_length=Length("goes_by")
... ).get()
>>> print(author.name_length, author.goes_by_length)
(14, None)
It can also be registered as a transform. For example:
>>> from django.db.models import CharField
>>> from django.db.models.functions import Length
>>> CharField.register_lookup(Length)
>>> # Get authors whose name is longer than 7 characters
>>> authors = Author.objects.filter(name__length__gt=7)
Lower
class Lower
(expression, **extra)[source]
Accepts a single text field or expression and returns the lowercase representation.
It can also be registered as a transform as described in Length.
Usage example:
>>> from django.db.models.functions import Lower
>>> Author.objects.create(name="Margaret Smith")
>>> author = Author.objects.annotate(name_lower=Lower("name")).get()
>>> print(author.name_lower)
margaret smith
LPad
class LPad
(expression, length, fill_text=Value(‘ ‘), **extra)[source]
Returns the value of the given text field or expression padded on the left side with fill_text
so that the resulting value is length
characters long. The default fill_text
is a space.
Usage example:
>>> from django.db.models import Value
>>> from django.db.models.functions import LPad
>>> Author.objects.create(name="John", alias="j")
>>> Author.objects.update(name=LPad("name", 8, Value("abc")))
1
>>> print(Author.objects.get(alias="j").name)
abcaJohn
LTrim
class LTrim
(expression, **extra)[source]
Similar to Trim, but removes only leading spaces.
MD5
class MD5
(expression, **extra)[source]
Accepts a single text field or expression and returns the MD5 hash of the string.
It can also be registered as a transform as described in Length.
Usage example:
>>> from django.db.models.functions import MD5
>>> Author.objects.create(name="Margaret Smith")
>>> author = Author.objects.annotate(name_md5=MD5("name")).get()
>>> print(author.name_md5)
749fb689816b2db85f5b169c2055b247
Ord
class Ord
(expression, **extra)[source]
Accepts a single text field or expression and returns the Unicode code point value for the first character of that expression. It works similar to Python’s ord() function, but an exception isn’t raised if the expression is more than one character long.
It can also be registered as a transform as described in Length. The default lookup name is ord
.
Usage example:
>>> from django.db.models.functions import Ord
>>> Author.objects.create(name="Margaret Smith")
>>> author = Author.objects.annotate(name_code_point=Ord("name")).get()
>>> print(author.name_code_point)
77
Repeat
class Repeat
(expression, number, **extra)[source]
Returns the value of the given text field or expression repeated number
times.
Usage example:
>>> from django.db.models.functions import Repeat
>>> Author.objects.create(name="John", alias="j")
>>> Author.objects.update(name=Repeat("name", 3))
1
>>> print(Author.objects.get(alias="j").name)
JohnJohnJohn
Replace
class Replace
(expression, text, replacement=Value(‘’), **extra)[source]
Replaces all occurrences of text
with replacement
in expression
. The default replacement text is the empty string. The arguments to the function are case-sensitive.
Usage example:
>>> from django.db.models import Value
>>> from django.db.models.functions import Replace
>>> Author.objects.create(name="Margaret Johnson")
>>> Author.objects.create(name="Margaret Smith")
>>> Author.objects.update(name=Replace("name", Value("Margaret"), Value("Margareth")))
2
>>> Author.objects.values("name")
<QuerySet [{'name': 'Margareth Johnson'}, {'name': 'Margareth Smith'}]>
Reverse
class Reverse
(expression, **extra)[source]
Accepts a single text field or expression and returns the characters of that expression in reverse order.
It can also be registered as a transform as described in Length. The default lookup name is reverse
.
Usage example:
>>> from django.db.models.functions import Reverse
>>> Author.objects.create(name="Margaret Smith")
>>> author = Author.objects.annotate(backward=Reverse("name")).get()
>>> print(author.backward)
htimS teragraM
Right
class Right
(expression, length, **extra)[source]
Returns the last length
characters of the given text field or expression.
Usage example:
>>> from django.db.models.functions import Right
>>> Author.objects.create(name="Margaret Smith")
>>> author = Author.objects.annotate(last_letter=Right("name", 1)).get()
>>> print(author.last_letter)
h
RPad
class RPad
(expression, length, fill_text=Value(‘ ‘), **extra)[source]
Similar to LPad, but pads on the right side.
RTrim
class RTrim
(expression, **extra)[source]
Similar to Trim, but removes only trailing spaces.
SHA1
, SHA224
, SHA256
, SHA384
, and SHA512
class SHA1
(expression, **extra)[source]
class SHA224
(expression, **extra)[source]
class SHA256
(expression, **extra)[source]
class SHA384
(expression, **extra)[source]
class SHA512
(expression, **extra)[source]
Accepts a single text field or expression and returns the particular hash of the string.
They can also be registered as transforms as described in Length.
Usage example:
>>> from django.db.models.functions import SHA1
>>> Author.objects.create(name="Margaret Smith")
>>> author = Author.objects.annotate(name_sha1=SHA1("name")).get()
>>> print(author.name_sha1)
b87efd8a6c991c390be5a68e8a7945a7851c7e5c
PostgreSQL
The pgcrypto extension must be installed. You can use the CryptoExtension migration operation to install it.
Oracle
Oracle doesn’t support the SHA224
function.
StrIndex
class StrIndex
(string, substring, **extra)[source]
Returns a positive integer corresponding to the 1-indexed position of the first occurrence of substring
inside string
, or 0 if substring
is not found.
Usage example:
>>> from django.db.models import Value as V
>>> from django.db.models.functions import StrIndex
>>> Author.objects.create(name="Margaret Smith")
>>> Author.objects.create(name="Smith, Margaret")
>>> Author.objects.create(name="Margaret Jackson")
>>> Author.objects.filter(name="Margaret Jackson").annotate(
... smith_index=StrIndex("name", V("Smith"))
... ).get().smith_index
0
>>> authors = Author.objects.annotate(smith_index=StrIndex("name", V("Smith"))).filter(
... smith_index__gt=0
... )
<QuerySet [<Author: Margaret Smith>, <Author: Smith, Margaret>]>
Warning
In MySQL, a database table’s collation determines whether string comparisons (such as the expression
and substring
of this function) are case-sensitive. Comparisons are case-insensitive by default.
Substr
class Substr
(expression, pos, length=None, **extra)[source]
Returns a substring of length length
from the field or expression starting at position pos
. The position is 1-indexed, so the position must be greater than 0. If length
is None
, then the rest of the string will be returned.
Usage example:
>>> # Set the alias to the first 5 characters of the name as lowercase
>>> from django.db.models.functions import Lower, Substr
>>> Author.objects.create(name="Margaret Smith")
>>> Author.objects.update(alias=Lower(Substr("name", 1, 5)))
1
>>> print(Author.objects.get(name="Margaret Smith").alias)
marga
Trim
class Trim
(expression, **extra)[source]
Returns the value of the given text field or expression with leading and trailing spaces removed.
Usage example:
>>> from django.db.models.functions import Trim
>>> Author.objects.create(name=" John ", alias="j")
>>> Author.objects.update(name=Trim("name"))
1
>>> print(Author.objects.get(alias="j").name)
John
Upper
class Upper
(expression, **extra)[source]
Accepts a single text field or expression and returns the uppercase representation.
It can also be registered as a transform as described in Length.
Usage example:
>>> from django.db.models.functions import Upper
>>> Author.objects.create(name="Margaret Smith")
>>> author = Author.objects.annotate(name_upper=Upper("name")).get()
>>> print(author.name_upper)
MARGARET SMITH
Window functions
There are a number of functions to use in a Window expression for computing the rank of elements or the Ntile of some rows.
CumeDist
class CumeDist
(*expressions, **extra)[source]
Calculates the cumulative distribution of a value within a window or partition. The cumulative distribution is defined as the number of rows preceding or peered with the current row divided by the total number of rows in the frame.
DenseRank
class DenseRank
(*expressions, **extra)[source]
Equivalent to Rank but does not have gaps.
FirstValue
class FirstValue
(expression, **extra)[source]
Returns the value evaluated at the row that’s the first row of the window frame, or None
if no such value exists.
Lag
class Lag
(expression, offset=1, default=None, **extra)[source]
Calculates the value offset by offset
, and if no row exists there, returns default
.
default
must have the same type as the expression
, however, this is only validated by the database and not in Python.
MariaDB and default
MariaDB doesn’t support the default
parameter.
LastValue
class LastValue
(expression, **extra)[source]
Comparable to FirstValue, it calculates the last value in a given frame clause.
Lead
class Lead
(expression, offset=1, default=None, **extra)[source]
Calculates the leading value in a given frame. Both offset
and default
are evaluated with respect to the current row.
default
must have the same type as the expression
, however, this is only validated by the database and not in Python.
MariaDB and default
MariaDB doesn’t support the default
parameter.
NthValue
class NthValue
(expression, nth=1, **extra)[source]
Computes the row relative to the offset nth
(must be a positive value) within the window. Returns None
if no row exists.
Some databases may handle a nonexistent nth-value differently. For example, Oracle returns an empty string rather than None
for character-based expressions. Django doesn’t do any conversions in these cases.
Ntile
class Ntile
(num_buckets=1, **extra)[source]
Calculates a partition for each of the rows in the frame clause, distributing numbers as evenly as possible between 1 and num_buckets
. If the rows don’t divide evenly into a number of buckets, one or more buckets will be represented more frequently.
PercentRank
class PercentRank
(*expressions, **extra)[source]
Computes the relative rank of the rows in the frame clause. This computation is equivalent to evaluating:
(rank - 1) / (total rows - 1)
The following table explains the calculation for the relative rank of a row:
Row # | Value | Rank | Calculation | Relative Rank |
---|---|---|---|---|
1 | 15 | 1 | (1-1)/(7-1) | 0.0000 |
2 | 20 | 2 | (2-1)/(7-1) | 0.1666 |
3 | 20 | 2 | (2-1)/(7-1) | 0.1666 |
4 | 20 | 2 | (2-1)/(7-1) | 0.1666 |
5 | 30 | 5 | (5-1)/(7-1) | 0.6666 |
6 | 30 | 5 | (5-1)/(7-1) | 0.6666 |
7 | 40 | 7 | (7-1)/(7-1) | 1.0000 |
Rank
class Rank
(*expressions, **extra)[source]
Comparable to RowNumber, this function ranks rows in the window. The computed rank contains gaps. Use DenseRank to compute rank without gaps.
RowNumber
class RowNumber
(*expressions, **extra)[source]
Computes the row number according to the ordering of either the frame clause or the ordering of the whole query if there is no partitioning of the window frame.