I have a very large table. It's currently in a MySQL database. I use django.

I need to iterate over each element of the table to pre-compute some particular data (maybe if I was better I could do otherwise but that's not the point).

I'd like to keep the iteration as fast as possible with a constant usage of memory.

As it is already clearly in Limiting Memory Use in a *Large* Django QuerySet and Why is iterating through a large Django QuerySet consuming massive amounts of memory?, a simple iteration over all objects in django will kill the machine as it will retrieve ALL objects from the database.

Towards a solution

First of all, to reduce your memory consumption you should be sure DEBUG is False (or monkey patch the cursor: turn off SQL logging while keeping settings.DEBUG?) to be sure django isn't storing stuff in connections for debug.

But even with that,

for model in Model.objects.all()

is a no go.

Not even with the slightly improved form:

for model in Model.objects.all().iterator()

Using iterator() will save you some memory by not storing the result of the cache internally (though not necessarily on PostgreSQL!); but will still retrieve the whole objects from the database, apparently.

A naive solution

The solution in the first question is to slice the results based on a counter by a chunk_size. There are several ways to write it, but basically they all come down to an OFFSET + LIMIT query in SQL.

something like:

qs = Model.objects.all()
counter = 0
count = qs.count()
while counter < count:     
    for model in qs[counter:counter+count].iterator()
        yield model
    counter += chunk_size

While this is memory efficient (constant memory usage proportional to chunk_size), it's really poor in term of speed: as OFFSET grows, both MySQL and PostgreSQL (and likely most DBs) will start choking and slowing down.

A better solution

A better solution is available in this post by Thierry Schellenbach. It filters on the PK, which is way faster than offsetting (how fast probably depends on the DB)

pk = 0
last_pk = qs.order_by('-pk')[0].pk
queryset = qs.order_by('pk')
while pk < last_pk:
    for row in qs.filter(pk__gt=pk)[:chunksize]:
        pk = row.pk
        yield row

This is starting to get satisfactory. Now Memory = O(C), and Speed ~= O(N)

Issues with the "better" solution

The better solution only works when the PK is available in the QuerySet. Unluckily, that's not always the case, in particular when the QuerySet contains combinations of distinct (group_by) and/or values (ValueQuerySet).

For that situation the "better solution" cannot be used.

Can we do better?

Now I'm wondering if we can go faster and avoid the issue regarding QuerySets without PK. Maybe using something that I found in other answers, but only in pure SQL: using cursors.

Since I'm quite bad with raw SQL, in particular in Django, here comes the real question:

how can we build a better Django QuerySet Iterator for large tables

My take from what I've read is that we should use server-side cursors (apparently (see references) using a standard Django Cursor would not achieve the same result, because by default both python-MySQL and psycopg connectors cache the results).

Would this really be a faster (and/or more efficient) solution?

Can this be done using raw SQL in django? Or should we write specific python code depending on the database connector?

Server Side cursors in PostgreSQL and in MySQL

That's as far as I could get for the moment...

a Django chunked_iterator()

Now, of course the best would have this method work as queryset.iterator(), rather than iterate(queryset), and be part of django core or at least a pluggable app.

Update Thanks to "T" in the comments for finding a django ticket that carry some additional information. Differences in connector behaviors make it so that probably the best solution would be to create a specific chunked method rather than transparently extending iterator (sounds like a good approach to me). An implementation stub exists, but there hasn't been any work in a year, and it does not look like the author is ready to jump on that yet.

Additional Refs:

  1. Why does MYSQL higher LIMIT offset slow the query down?
  2. How can I speed up a MySQL query with a large offset in the LIMIT clause?
  3. http://explainextended.com/2009/10/23/mysql-order-by-limit-performance-late-row-lookups/
  4. postgresql: offset + limit gets to be very slow
  5. Improving OFFSET performance in PostgreSQL
  6. http://www.depesz.com/2011/05/20/pagination-with-fixed-order/
  7. How to get a row-by-row MySQL ResultSet in python Server Side Cursor in MySQL


Django 1.6 is adding persistent database connections

Django Database Persistent Connections

This should facilitate, under some conditions, using cursors. Still it's outside my current skills (and time to learn) how to implement such a solution..

Also, the "better solution" definitely does not work in all situations and cannot be used as a generic approach, only a stub to be adapted case by case...

  • 4
    Wow, that was a really well-researched question! :) – Daniel Eriksson Jan 3 '13 at 18:12
  • Thanks @DanielEriksson, I thought I would manage to get it all working by myself but I'm not yet there... – Stefano Jan 3 '13 at 18:14
  • Oh, and additional solutions involve building custom indexes (eg. see the Pagination solution), but I was hoping for a more general solution – Stefano Jan 3 '13 at 18:15
  • 1
    I think this is actually being done right now, check this out: code.djangoproject.com/ticket/16614 It seems that for .iterator and similar use-cases the cursor will now be an SSCursor, which is what you want instead of the default, and this will happen transparently. – t.dubrownik Jan 4 '13 at 1:56
  • @t.dubrownik wow! man I searched, but I did not find that in the most obvious place. There is precious additional information there, although not full consensus on whether that could happen transparently or through a separate method chunked; unluckily it sounds like development is stalled. Let's see if we collect something interesting. I'll go update my question :) – Stefano Jan 4 '13 at 7:42

The essential answer: use raw SQL with server-side cursors.

Sadly, until Django 1.5.2 there is no formal way to create a server-side MySQL cursor (not sure about other database engines). So I wrote some magic code to solve this problem.

For Django 1.5.2 and MySQLdb 1.2.4, the following code will work. Also, it's well commented.

Caution: This is not based on public APIs, so it will probably break in future Django versions.

# This script should be tested under a Django shell, e.g., ./manage.py shell

from types import MethodType

import MySQLdb.cursors
import MySQLdb.connections
from django.db import connection
from django.db.backends.util import CursorDebugWrapper

def close_sscursor(self):
    """An instance method which replace close() method of the old cursor.

    Closing the server-side cursor with the original close() method will be
    quite slow and memory-intensive if the large result set was not exhausted,
    because fetchall() will be called internally to get the remaining records.
    Notice that the close() method is also called when the cursor is garbage 

    This method is more efficient on closing the cursor, but if the result set
    is not fully iterated, the next cursor created from the same connection
    won't work properly. You can avoid this by either (1) close the connection 
    before creating a new cursor, (2) iterate the result set before closing 
    the server-side cursor.
    if isinstance(self, CursorDebugWrapper):
        self.cursor.cursor.connection = None
        # This is for CursorWrapper object
        self.cursor.connection = None

def get_sscursor(connection, cursorclass=MySQLdb.cursors.SSCursor):
    """Get a server-side MySQL cursor."""
    if connection.settings_dict['ENGINE'] != 'django.db.backends.mysql':
        raise NotImplementedError('Only MySQL engine is supported')
    cursor = connection.cursor()
    if isinstance(cursor, CursorDebugWrapper):
        # Get the real MySQLdb.connections.Connection object
        conn = cursor.cursor.cursor.connection
        # Replace the internal client-side cursor with a sever-side cursor
        cursor.cursor.cursor = conn.cursor(cursorclass=cursorclass)
        # This is for CursorWrapper object
        conn = cursor.cursor.connection
        cursor.cursor = conn.cursor(cursorclass=cursorclass)
    # Replace the old close() method
    cursor.close = MethodType(close_sscursor, cursor)
    return cursor

# Get the server-side cursor
cursor = get_sscursor(connection)

# Run a query with a large result set. Notice that the memory consumption is low.
cursor.execute('SELECT * FROM million_record_table')

# Fetch a single row, fetchmany() rows or iterate it via "for row in cursor:"

# You can interrupt the iteration at any time. This calls the new close() method,
# so no warning is shown.

# Connection must be close to let new cursors work properly. see comments of
# close_sscursor().

Simple Answer

If you just need to iterate over the table itself without doing anything fancy, Django comes with a builtin iterator:


This causes Django to clean up it's own cache to reduce memory use. Note that for truly large tables, this may not be enough.

Complex Answer

If you are doing something more complex with each object or have a lot of data, you have to write your own. The following is a queryset iterator that splits the queryset into chunks and is not much slower than the basic iterator (it will be a linear number of database queries, as opposed to 1, but it will only one query per 1,000 rows). This function pages by primary key, which is necessary for efficient implementation since offset is a linear time operation in most SQL databases.

def queryset_iterator(queryset, page_size=1000):
    if not queryset:
    max_pk = queryset.order_by("-pk")[0].pk
    # Scale the page size up by the average density of primary keys in the queryset
    adjusted_page_size = int(page_size * max_pk / queryset.count())
    pages = int(max_pk / adjusted_page_size) + 1
    for page_num in range(pages):
        lower = page_num * adjusted_page_size
        page = queryset.filter(pk__gte=lower, pk__lt=lower+page_size)
        for obj in page:
            yield obj

Use looks like:

for obj in queryset_iterator(Model.objects.all()):
    # do stuff

This code has three assumptions:

  1. Your primary keys are integers (this will not work for UUID primary keys).
  2. The primary keys of the queryset are at least somewhat uniformly distributed. If this is not true, the adjusted_page_size can end up too large and you may get one or several massive pages as part of your iteration.

To give a sense of the overhead, I tested this on a Postgres table with 40,000 entries. The queryset_iterator adds about 80% to the iteration time vs raw iteration (2.2 seconds vs 1.2 seconds). That overhead does not vary substantially for page sizes between 200 and 10,000, though it starts going up below 200.


There is another option available. It wouldn't make the iteration faster, (in fact it would probably slow it down), but it would make it use far less memory. Depending on your needs this may be appropriate.

large_qs = MyModel.objects.all().values_list("id", flat=True)
for model_id in large_qs:
    model_object = MyModel.objects.get(id=model_id)
    # do whatever you need to do with the model here

Only the ids are loaded into memory, and the objects are retrieved and discarded as needed. Note the increased database load and slower runtime, both tradeoffs for the reduction in memory usage.

I've used this when running async scheduled tasks on worker instances, for which it doesn't really matter if they are slow, but if they try to use way too much memory they may crash the instance and therefore abort the process.

  • Thanks Clay, it is indeed an option that I forgot to add but in my case this didn't work. My database has about 30 million rows, and the PK is a string of 12 characters (not my choice!). This makes retrieving a list of IDs VERY memory hungry, and iterating over each object makes the retrieval EXTREMELY slow! – Stefano Jan 8 '13 at 9:00
  • For reference, using an improved version of the "better solution" up that that only retrieves required values made working over those 30M rows run in less than 30 minutes on a 512Mb, double core instance, which is already decent. The naive solution would keep slowing down and I never were patient enough to wait for the end (hours!). As you say, your solution will be slower, but also retrieving the list of IDs make it require quite a lot of memory. – Stefano Jan 8 '13 at 9:05
  • Yeah, it looks like on its own this will not work for you. But, as you mentioned, using the option to only retrieve what you need in conjunction with some other technique might be helpful. – Clay Wardell Jan 8 '13 at 16:06

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