A queryset is an object that represents a database query using a specific Model. It is lazy, meaning that it does not hit the database until you iterate over its matching rows (model instances). To create a base queryset for a model class, use:
qs = Person.objects_in(database)
This queryset matches all Person instances in the database. You can get these instances using iteration:
for person in qs:
print(person.first_name, person.last_name)
The filter
and exclude
methods are used for filtering the matching instances. Calling these methods returns a new queryset instance, with the added conditions. For example:
>>> qs = Person.objects_in(database)
>>> qs = qs.filter(F.like(Person.first_name, 'V%')).exclude(Person.birthday < '2000-01-01')
>>> qs.conditions_as_sql()
"first_name LIKE 'V%' AND NOT (birthday < '2000-01-01')"
It is possible to specify several expressions to filter or exclude by, and they will be ANDed together:
>>> qs = Person.objects_in(database).filter(Person.last_name == 'Smith', Person.height > 1.75)
>>> qs.conditions_as_sql()
"last_name = 'Smith' AND height > 1.75"
For compound conditions you can use the overloaded operators &
(AND), |
(OR) and ~
(NOT):
>>> qs = Person.objects_in(database)
>>> qs = qs.filter(((Person.first_name == 'Ciaran') & (Person.last_name == 'Carver')) | (Person.height <= 1.8) & ~(Person.first_name = 'David'))
>>> qs.conditions_as_sql()
"((first_name = 'Ciaran' AND last_name = 'Carver') OR height <= 1.8) AND (NOT (first_name = 'David'))"
Note that Python's bitwise operators (&
, |
, ~
, ^
) have higher precedence than comparison operators, so always use parentheses when combining these two types of operators in an expression. Otherwise the resulting SQL might be different than what you would expect.
Filtering queries using ClickHouse's IN
and NOT IN
operators requires using the isIn
and isNotIn
functions (trying to use Python's in
keyword will not work!).
For example:
# Is it Monday, Tuesday or Wednesday?
F.isIn(F.toDayOfWeek(F.now()), [1, 2, 3])
# This will not work:
F.toDayOfWeek(F.now()) in [1, 2, 3]
In case of model fields, there is a simplified syntax:
# Filtering using F.isIn:
qs.filter(F.isIn(Person.first_name, ['Robert', 'Rob', 'Robbie']))
# Simpler syntax using isIn directly on the field:
qs.filter(Person.first_name.isIn(['Robert', 'Rob', 'Robbie']))
The isIn
and isNotIn
functions expect either a list/tuple of values, or another queryset (a subquery). For example if we want to select only people with Irish last names:
# Last name is in a list of values
qs = Person.objects_in(database).filter(Person.last_name.isIn(["Murphy", "O'Sullivan"]))
# Last name is in a subquery
subquery = IrishLastName.objects_in(database).only("name")
qs = Person.objects_in(database).filter(Person.last_name.isIn(subquery))
By default conditions from filter
and exclude
methods are add to WHERE
clause.
For better aggregation performance you can add them to PREWHERE
section by adding a prewhere=True
parameter:
>>> qs = Person.objects_in(database)
>>> qs = qs.filter(F.like(Person.first_name, 'V%'), prewhere=True)
>>> qs.conditions_as_sql(prewhere=True)
"first_name LIKE 'V%'"
Prior to version 2 of the ORM, filtering conditions were limited to a predefined set of operators, and complex expressions were not supported. This old syntax is still available, so you can use it alongside or even intermixed with new-style functions and expressions.
The old syntax uses keyword arguments to the filter
and exclude
methods, that are built as <fieldname>__<operator>=<value>
(two underscores separate the field name from the operator). In case no operator is given, eq
is used by default. For example:
qs = Position.objects.in(database)
# New style
qs = qs.filter(Position.x > 100, Position.y < 20, Position.terrain == 'water')
# Old style
qs = qs.filter(x__gt=100, y__lt=20, terrain='water')
Below are all the supported operators.
Operator | Equivalent SQL | Comments |
---|---|---|
eq |
field = value |
|
ne |
field != value |
|
gt |
field > value |
|
gte |
field >= value |
|
lt |
field < value |
|
lte |
field <= value |
|
between |
field BETWEEN value1 AND value2 |
|
in |
field IN (values) |
|
not_in |
field NOT IN (values) |
|
contains |
field LIKE '%value%' |
For string fields only |
startswith |
field LIKE 'value%' |
For string fields only |
endswith |
field LIKE '%value' |
For string fields only |
icontains |
lowerUTF8(field) LIKE lowerUTF8('%value%') |
For string fields only |
istartswith |
lowerUTF8(field) LIKE lowerUTF8('value%') |
For string fields only |
iendswith |
lowerUTF8(field) LIKE lowerUTF8('%value') |
For string fields only |
iexact |
lowerUTF8(field) = lowerUTF8(value) |
For string fields only |
Use the count
method to get the number of matches:
Person.objects_in(database).count()
To check if there are any matches at all, you can use any of the following equivalent options:
if qs.count(): ...
if bool(qs): ...
if qs: ...
The sorting order of the results can be controlled using the order_by
method:
qs = Person.objects_in(database).order_by('last_name', 'first_name')
The default order is ascending. To use descending order, add a minus sign before the field name:
qs = Person.objects_in(database).order_by('-height')
If you do not use order_by
, the rows are returned in arbitrary order.
When some of the model fields aren't needed, it is more efficient to omit them from the query. This is especially true when there are large fields that may slow the query down. Use the only
method to specify which fields to retrieve:
qs = Person.objects_in(database).only('first_name', 'birthday')
Adds a DISTINCT clause to the query, meaning that any duplicate rows in the results will be omitted.
>>> Person.objects_in(database).only('first_name').count()
100
>>> Person.objects_in(database).only('first_name').distinct().count()
94
This method can be used only with CollapsingMergeTree
engine.
Adds a FINAL modifier to the query, meaning that the selected data is fully "collapsed" by the engine's sign field.
>>> Person.objects_in(database).count()
100
>>> Person.objects_in(database).final().count()
94
It is possible to get a specific item from the queryset by index:
qs = Person.objects_in(database).order_by('last_name', 'first_name')
first = qs[0]
It is also possible to get a range a instances using a slice. This returns a queryset, that you can either iterate over or convert to a list.
qs = Person.objects_in(database).order_by('last_name', 'first_name')
first_ten_people = list(qs[:10])
next_ten_people = list(qs[10:20])
You should use order_by
to ensure a consistent ordering of the results.
Trying to use negative indexes or a slice with a step (e.g. [0 : 100 : 2]) is not supported and will raise an AssertionError
.
Similar to Database.paginate
, you can go over the queryset results one page at a time:
>>> qs = Person.objects_in(database).order_by('last_name', 'first_name')
>>> page = qs.paginate(page_num=1, page_size=10)
>>> print(page.number_of_objects)
2507
>>> print(page.pages_total)
251
>>> for person in page.objects:
>>> # do something
The paginate
method returns a namedtuple
containing the following fields:
objects
- the list of objects in this pagenumber_of_objects
- total number of objects in all pagespages_total
- total number of pagesnumber
- the page number, starting from 1; the special value -1 may be used to retrieve the last pagepage_size
- the number of objects per page
Note that you should use QuerySet.order_by
so that the ordering is unique, otherwise there might be inconsistencies in the pagination (such as an instance that appears on two different pages).
To delete all records that match a queryset's conditions use the delete
method:
Person.objects_in(database).filter(first_name='Max').delete()
To update records that match a queryset's conditions call the update
method and provide the field names to update and the expressions to use (as keyword arguments):
Person.objects_in(database).filter(first_name='Max').update(first_name='Maximilian')
Note a few caveats:
- ClickHouse cannot update columns that are used in the calculation of the primary or the partition key.
- Mutations happen in the background, so they are not immediate.
- Only tables in the
MergeTree
family support mutations.
It is possible to use aggregation functions over querysets using the aggregate
method. The simplest form of aggregation works over all rows in the queryset:
>>> qs = Person.objects_in(database).aggregate(average_height=F.avg(Person.height))
>>> print(qs.count())
1
>>> for row in qs: print(row.average_height)
1.71
The returned row or rows are no longer instances of the base model (Person
in this example), but rather instances of an ad-hoc model that includes only the fields specified in the call to aggregate
.
You can pass fields from the model that will be included in the query. By default, they will be also used in the GROUP BY clause. For example to count the number of people per last name you could do this:
qs = Person.objects_in(database).aggregate(Person.last_name, num=F.count())
The underlying SQL query would be something like this:
SELECT last_name, count() AS num
FROM person
GROUP BY last_name
If you would like to control the GROUP BY explicitly, use the group_by
method. This is useful when you need to group by a calculated field, instead of a field that exists in the model. For example, to count the number of people born on each weekday:
qs = Person.objects_in(database).aggregate(weekday=F.toDayOfWeek(Person.birthday), num=F.count()).group_by('weekday')
This queryset is translated to:
SELECT toDayOfWeek(birthday) AS weekday, count() AS num
FROM person
GROUP BY weekday
After calling aggregate
you can still use most of the regular queryset methods, such as count
, order_by
and paginate
. It is not possible, however, to call only
or aggregate
. It is also not possible to filter the aggregated queryset on calculated fields, only on fields that exist in the model.
If you limit aggregation results, it might be useful to get total aggregation values for all rows.
To achieve this, you can use with_totals
method. It will return extra row (last) with
values aggregated for all rows suitable for filters.
qs = Person.objects_in(database).aggregate(Person.first_name, num=F.count()).with_totals().order_by('-count')[:3]
>>> print(qs.count())
4
>>> for row in qs:
>>> print("'{}': {}".format(row.first_name, row.count))
'Cassandra': 2
'Alexandra': 2
'': 100
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