There are many solutions to serialize a small dictionary: json.loads/json.dumps, pickle, shelve, ujson, or even by using sqlite.

But when dealing with possibly 100 GB of data, it's not possible anymore to use such modules that would possibly rewrite the whole data when closing / serializing.

redis is not really an option because it uses a client/server scheme.

Question: Which key:value store, serverless, able to work with 100+ GB of data, are frequently used in Python?

I'm looking for a solution with a standard "Pythonic" d[key] = value syntax:

import mydb
d = mydb.mydb('myfile.db')
d['hello'] = 17          # able to use string or int or float as key
d[183] = [12, 14, 24]    # able to store lists as values (will probably internally jsonify it?)
d.flush()                # easy to flush on disk 

Note: BsdDB (BerkeleyDB) seems to be deprecated. There seems to be a LevelDB for Python, but it doesn't seem well-known - and I haven't found a version which is ready to use on Windows. Which ones would be the most common ones?

Linked questions: Use SQLite as a key:value store, Flat file NoSQL solution

  • 3
    SQLite should work great. Did you have any problems using it? Its the DBMS that is small but the DB itself can be large. See stackoverflow.com/questions/14451624/…
    – Himanshu
    Nov 11, 2017 at 1:58
  • @Himanshu It's the fact the usage with SQLite is not as simple as db[key] = value or db.put('key', 'value'), but uses SQL instead... And I'd like to avoid INSERT into TABLE or SELECT ... for just a simple key:value db[key] = value set/get.
    – Basj
    Nov 11, 2017 at 2:01
  • Can you describe the data more? 100 GB of what? How large is the smallest/median/largest value? How many key/value pairs make up the 100 GB? Nov 11, 2017 at 2:21
  • You may be able to get this working in dask but I've never actually used it, it's on my to-do. Apparently it runs on a single system too. Or you can always have MongoDB - there's nothing stopping you running that on localhost. I'm not sure what your requirement for serverless stems from, you might not have a choice for such large data stores on a single PC.
    – roganjosh
    Nov 11, 2017 at 3:16
  • 2
    Python's dbm module is perfect for this. I just checked and it doesn't load anything into memory and has an interface identical to a dict. I can't post an answer because it's closed, so I decided to post here. Jan 6, 2020 at 20:37

7 Answers 7


You can use sqlitedict which provides key-value interface to SQLite database.

SQLite limits page says that theoretical maximum is 140 TB depending on page_size and max_page_count. However, default values for Python 3.5.2-2ubuntu0~16.04.4 (sqlite3 2.6.0), are page_size=1024 and max_page_count=1073741823. This gives ~1100 GB of maximal database size which fits your requirement.

You can use the package like:

from sqlitedict import SqliteDict

mydict = SqliteDict('./my_db.sqlite', autocommit=True)
mydict['some_key'] = any_picklable_object
for key, value in mydict.items():
    print(key, value)


About memory usage. SQLite doesn't need your dataset to fit in RAM. By default it caches up to cache_size pages, which is barely 2MiB (the same Python as above). Here's the script you can use to check it with your data. Before run:

pip install lipsum psutil matplotlib psrecord sqlitedict


#!/usr/bin/env python3

import os
import random
from contextlib import closing

import lipsum
from sqlitedict import SqliteDict

def main():
    with closing(SqliteDict('./my_db.sqlite', autocommit=True)) as d:
        for _ in range(100000):
            v = lipsum.generate_paragraphs(2)[0:random.randint(200, 1000)]
            d[os.urandom(10)] = v

if __name__ == '__main__':

Run it like ./sqlitedct.py & psrecord --plot=plot.png --interval=0.1 $!. In my case it produces this chart: chart

And database file:

$ du -h my_db.sqlite 
84M my_db.sqlite
  • Very nice benchmark, thank you @saaj! Being curious: what does with closing(...) as ...: do?
    – Basj
    Jan 18, 2018 at 10:21
  • About the graph CPU y-axis between 0 and 200%, average 150%, is the y-axis correct?
    – Basj
    Jan 18, 2018 at 10:22
  • @Basj 1) contextlib.closing. 2) I think it is, as sqlite3 creates own thread which releases GIL when operating in _sqlite3 binary. So it gets over 100%.
    – saaj
    Jan 18, 2018 at 12:25
  • Excellent answer, I updated mine accordingly stackoverflow.com/a/48298904/140837
    – amirouche
    Feb 5, 2018 at 3:19
  • 1
    There's also diskcache which is pure-Python, requires no server, fast and also built atop SQLite. The largest known diskcache database is 75GB.
    – GrantJ
    Nov 9, 2018 at 22:09

LMDB (Lightning Memory-Mapped Database) is a very fast key-value store which has Python bindings and can handle huge database files easily.

There is also the lmdbm wrapper which offers the Pythonic d[key] = value syntax.

By default it only supports byte values, but it can easily be extended to use a serializer (json, msgpack, pickle) for other kinds of values.

import json
from lmdbm import Lmdb

class JsonLmdb(Lmdb):
  def _pre_key(self, value):
    return value.encode("utf-8")
  def _post_key(self, value):
    return value.decode("utf-8")
  def _pre_value(self, value):
    return json.dumps(value).encode("utf-8")
  def _post_value(self, value):
    return json.loads(value.decode("utf-8"))

with JsonLmdb.open("test.db", "c") as db:
  db["key"] = {"some": "object"}
  obj = db["key"]
  print(obj["some"])  # prints "object"

Some benchmarks. Batched inserts (1000 items each) were used for lmdbm and sqlitedict. Write performance suffers a lot for non-batched inserts for these because each insert opens a new transaction by default. dbm refers to stdlib dbm.dumb. Tested on Win 7, Python 3.8, SSD.

continuous writes in seconds

| items | lmdbm | pysos |sqlitedict|   dbm   |
|     10| 0.0000| 0.0000|   0.01600|  0.01600|
|    100| 0.0000| 0.0000|   0.01600|  0.09300|
|   1000| 0.0320| 0.0460|   0.21900|  0.84200|
|  10000| 0.1560| 2.6210|   2.09100|  8.42400|
| 100000| 1.5130| 4.9140|  20.71700| 86.86200|
|1000000|18.1430|48.0950| 208.88600|878.16000|

random reads in seconds

| items | lmdbm | pysos |sqlitedict|  dbm   |
|     10| 0.0000|  0.000|    0.0000|  0.0000|
|    100| 0.0000|  0.000|    0.0630|  0.0150|
|   1000| 0.0150|  0.016|    0.4990|  0.1720|
|  10000| 0.1720|  0.250|    4.2430|  1.7470|
| 100000| 1.7470|  3.588|   49.3120| 18.4240|
|1000000|17.8150| 38.454|  516.3170|196.8730|

For the benchmark script see https://github.com/Dobatymo/lmdb-python-dbm/blob/master/benchmark.py

  • Thank you for your answer. Can you include sample code (with imports etc.) in your answer, so that it's better for future reference and for people who want to try quickly this solution.
    – Basj
    Nov 6, 2020 at 18:45
  • Can you also include some benchmarking? Thank you for sharing this library!
    – 0x90
    Nov 11, 2020 at 2:16
  • I tried a mini benchmark here gist.github.com/dagnelies/eae73f7341ef00068c3d27cd488f33bc but performance looked quite disastrous. Did I do something wrong? Inserting 100k small key/value pairs took LMDB whopping 6 minutes!?! ...as a baseline comparison, pysos does it in ~4 seconds.
    – dagnelies
    Nov 25, 2020 at 8:59
  • 1
    @dagnelies You might want to use .update() for batch inserts, otherwise each insert will be one transaction. This should give you at least 10 times the performance. LMDB is a full featured database with ACID transactions and concurrent access. Also it doesn't store all keys in memory. Writes are thus more expensive. Your benchmark does not concern read performance, memory usage, crash safety or concurrency. When I have time, I will try to add some more comprehensive comparisons.
    – C. Yduqoli
    Nov 26, 2020 at 6:37
  • 1
    Thanks for this great answer! I am working on a 300 million items one-to-many lookup table. I tried sqlitedict, wiredtiger, pysos and lmdb. I can confirm using Lmdb.update(<dict>) is key for a decent write performance. Inserting elements one-by-one, lmdb was able to write ~1k items per second, for sqlitedict and pysos it was ~3k/s and ~80k/s, respectively. With wiredtiger I got some tough errors and the support is sparse. Finally, inserting 100k at a time into lmdb reaches an impressing 100-500k/s speed. Also it's light on memory, unlike some of the other libraries here.
    – deeenes
    Sep 17, 2021 at 12:57

I would consider HDF5 for this. It has several advantages:

  • Usable from many programming languages.
  • Usable from Python via the excellent h5py package.
  • Battle tested, including with large data sets.
  • Supports variable-length string values.
  • Values are addressable by a filesystem-like "path" (/foo/bar).
  • Values can be arrays (and usually are), but do not have to be.
  • Optional built-in compression.
  • Optional "chunking" to allow writing chunks incrementally.
  • Does not require loading the entire data set into memory at once.

It does have some disadvantages too:

  • Extremely flexible, to the point of making it hard to define a single approach.
  • Complex format, not feasible to use without the official HDF5 C library (but there are many wrappers, e.g. h5py).
  • Baroque C/C++ API (the Python one is not so).
  • Little support for concurrent writers (or writer + readers). Writes might need to lock at a coarse granularity.

You can think of HDF5 as a way to store values (scalars or N-dimensional arrays) inside a hierarchy inside a single file (or indeed multiple such files). The biggest problem with just storing your values in a single disk file would be that you'd overwhelm some filesystems; you can think of HDF5 as a filesystem within a file which won't fall down when you put a million values in one "directory."

  • 4
    HDF5 is not a database, it's serialization format. It's requires to load the whole in memory.
    – amirouche
    Jan 17, 2018 at 10:25
  • 1
    Thank you. Can you include 3 or 4 lines of code showing how to use it, like in the (edited) question? i.e. import ... then creation of DB then d[key] = value then flush it to disk.
    – Basj
    Jan 17, 2018 at 11:52
  • 8
    @amirouche: Obviously HDF5 is not a database. The question did not ask for a database. HDF5 does not require loading the whole of anything into memory--you can load slices, "hyperslabs", single arrays or attributes in a hierarchical file, etc. It absolutely does not require loading anything more than you want into memory. Anyway OP's data is on the order of 100 GB, and 100 GB of main memory is easily found on commodity servers and even some desktops these days. Jan 17, 2018 at 12:59
  • 1
    @Basj: Please see h5py's excellent Quick Start tutorial here: docs.h5py.org/en/latest/quick.html - it has code for exactly what you want. Jan 17, 2018 at 13:01
  • Would this be optimal for text data? May 26, 2019 at 20:03

The shelve module in the standard library does just that:

import shelve
with shelve.open('myfile.db') as d:
    d['hello'] = 17  # Auto serializes any Python object with pickle
    d[str(183)] = [12, 14, 24]  # Keys, however, must be strings
    d.sync()  # Explicitly write to disc (automatically performed on close)

This uses the python dbm module to save and load data from disk without loading the entire thing.

Example with dbm:

import dbm, json
with dbm.open('myfile2.db', 'c') as d:
    d['hello'] = str(17)
    d[str(183)] = json.dumps([12, 14, 24])

However, there are two considerations when using shelve:

  • It uses pickle for serialization. What this means is the data is coupled with Python and possibly the python version used to save the data. If this is a concern, the dbm module can be used directly (same interface, but only strings can be used as keys/values).
  • The Windows implementation seems to have bad performance

For this reason, the following third party options copied from here would be good options:

  • semidb - Faster cross platform dbm implementation
  • UnQLite - More feature-filled serverless database
  • More mentioned in the link
  • 1
    Thanks for your answer! I added a dbm example for future reference, I hope it's ok for you.
    – Basj
    Apr 29, 2020 at 13:16

I know it's an old question, but I wrote something like this long ago:


It works like a normal python dict, but has the advantage that it's much more efficient than shelve on windows and is also cross-platform, unlike shelve where the data storage differs based on the OS.

To install:

pip install pysos


import pysos
db = pysos.Dict('somefile')
db['hello'] = 'persistence!'

EDIT: Performance

Just to give a ballpark figure, here is a mini benchmark (on my windows laptop):

import pysos
t = time.time()
import time
N = 100 * 1000
db = pysos.Dict("test.db")
for i in range(N):
    db["key_" + str(i)] = {"some": "object_" + str(i)}

print('PYSOS time:', time.time() - t)
# => PYSOS time: 3.424309253692627

The resulting file was about 3.5 Mb big. ...So, very roughly speeking, you could insert 1 mb of data per second.

EDIT: How it works

It writes every time you set a value, but only the key/value pair. So the cost of adding/updating/deleting an item is always the same, although adding only is "better" because lots of updating/deleting leads to data fragmentation in the file (wasted junk bytes). What is kept in memory is the mapping (key -> location in the file), so you just have to ensure there is enough RAM for all those keys. SSD is also highly recommended. 100 MB is easy and fast. 100 GB like posted originally will be a lot, but doable. Even raw reading/writing 100 GB takes quite some time.

  • Nice, I'm going to try it! When is it written to disk? Do we need to do db.flush() every now and then? Also, if we have 100 MB data in it, does resaving to disk imply rewriting all 100 MB or only what has changed since last write?
    – Basj
    Jun 21, 2020 at 8:57
  • it writes every time you set a value, but only the key/value pair. So the cost of adding/updating/deleting an item is always the same, although adding only is "better" because lots of updating/deleting leads to data fragmentation in the file (wasted junk bytes). What is kept in memory is the mapping (key -> location in the file), so you just have to ensure there is enough RAM for all those keys. SSD is also highly recommended. 100 MB is easy and fast. 100 GB like posted originally will be a lot, but doable. Even raw reading/writing 100 GB takes quite some time.
    – dagnelies
    Jun 23, 2020 at 7:31
  • Thank you. Could you include this useful information in the answer for future reference @dagnelies? because this is really the important part.
    – Basj
    Jun 23, 2020 at 7:33
  • How is pysos different from docs.python.org/3/library/dbm.html#module-dbm.dumb ? It seems to work the same way (keeping only the mapping in memory, write every time, ...)
    – C. Yduqoli
    Nov 18, 2020 at 8:36
  • 1
    @C.Yduqoli: if I remember right, pysos had by far better performances than the "dumb" dbm at the time which sucked badly. However, please keep in mind that this was 5 years ago, things might have evolved during this time. It would be nice if you make a small benchmark and post the results. Aside from that pysos also encodes your key/value objects as json and the "db" file is readable, while dbm deals with bytes as key/values encoded in binary files. There are a few more details where they probably differ, but both share the similarity of being a key/value store at their core.
    – dagnelies
    Nov 19, 2020 at 20:01

First, bsddb (or under it's new name Oracle BerkeleyDB) is not deprecated.

From experience LevelDB / RocksDB / bsddb are slower than wiredtiger, that's why I recommend wiredtiger.

wiredtiger is the storage engine for mongodb so it's well tested in production. There is little or no use of wiredtiger in Python outside my AjguDB project; I use wiredtiger (via AjguDB) to store and query wikidata and concept which around 80GB.

Here is an example class that allows mimick the python2 shelve module. Basically, it's a wiredtiger backend dictionary where keys can only be strings:

import json

from wiredtiger import wiredtiger_open

WT_NOT_FOUND = -31803

class WTDict:
    """Create a wiredtiger backed dictionary"""

    def __init__(self, path, config='create'):
        self._cnx = wiredtiger_open(path, config)
        self._session = self._cnx.open_session()
        # define key value table
        self._session.create('table:keyvalue', 'key_format=S,value_format=S')
        self._keyvalue = self._session.open_cursor('table:keyvalue')

    def __enter__(self):
        return self

    def close(self):

    def __exit__(self, *args, **kwargs):

    def _loads(self, value):
        return json.loads(value)

    def _dumps(self, value):
        return json.dumps(value)

    def __getitem__(self, key):
        if self._keyvalue.search() == WT_NOT_FOUND:
            raise KeyError()
        out = self._loads(self._keyvalue.get_value())
        return out

    def __setitem__(self, key, value):

Here the adapted test program from @saaj answer:

#!/usr/bin/env python3

import os
import random

import lipsum
from wtdict import WTDict

def main():
    with WTDict('wt') as wt:
        for _ in range(100000):
            v = lipsum.generate_paragraphs(2)[0:random.randint(200, 1000)]
            wt[os.urandom(10)] = v

if __name__ == '__main__':

Using the following command line:

python test-wtdict.py & psrecord --plot=plot.png --interval=0.1 $!

I generated the following diagram:

wt performance without wal

$ du -h wt
60M wt

When write-ahead-log is active:

wt performance with wal

$ du -h wt
260M    wt

This is without performance tunning and compression.

Wiredtiger has no known limit until recently, the documentation was updated to the following:

WiredTiger supports petabyte tables, records up to 4GB, and record numbers up to 64-bits.


  • Thanks. Can you give an example of code using wiredtiger? Is it possible to use it with a simple API like import wiredtiger wt = wiredtiger.wiredtiger('myfile.db') wt['hello'] = 17 wt[183] = [12, 14, 24] wt.flush() i.e. the main requirements are: 1) wt[key] = value syntax 2) able to use string or int or float as key 3) able to store lists as values 4) easy to flush on disk
    – Basj
    Jan 17, 2018 at 11:38
  • Is it for Python 2 or Python 3?
    – amirouche
    Jan 17, 2018 at 13:20
  • Using the wiredtiger engine is a cool idea. However the Python bindings seem to be maintained poorly.
    – C. Yduqoli
    Dec 8, 2020 at 7:36
  • @C.Yduqoli what are the python bindings you are referring to? They are maintained by mongodb.
    – amirouche
    Dec 11, 2020 at 17:57
  • 1
    @amirouche the official ones here pypi.org/project/wiredtiger There is no windows support for example, although the wiredtiger C code does support Windows.
    – C. Yduqoli
    Dec 14, 2020 at 0:52

Another solution that is worth taking a look on is DiskCache's Index (API docs). It's atomic, thread and process-safe and it has transactions (see features comparison here).

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