• Python 3
  • IPython 3.2

Every time I shut down a IPython notebook and re-open it, I have to re-run all the cells. But some cells involve intensive computation.

By contrast, knitr in R save the results in a cache directory by default so only new code and new settings would invoke computation.

I looked at ipycache but it seems to cache a cell instead of the notebook. Is there a counterpart of cache of knitr in IPython?

  • 2
    I don't know if there is such capability in Ipython, but you could simply cache your expensive computations to disk with for instance joblib.Memory.
    – rth
    Jul 6, 2015 at 22:17

5 Answers 5


Unfortunately, it doesn't seem like there is something as convenient as an automatic cache. The %store magic option is close, but requires you to do the caching and reloading manually and explicitly.

In your Jupyter notebook:

a = 1
%store a

Now, let's say you close the notebook and the kernel gets restarted. You no longer have access to the local variables. However, you can reload the variables you've stored using the -r option.

%store -r a
print a # Should print 1
  • Does this work between two different notebooks? Seems to be the case
    – BND
    Sep 10, 2020 at 19:03

In fact the functionality you ask is already there, no need to re-implement it manually by doing your dumps .

You can use the use the %store or maybe better the %%cache magic (extension) to store the results of these intermittently cells, so they don't have to be recomputed (see https://github.com/rossant/ipycache)

It is as simple as:

%load_ext ipycache

Then, in a cell e.g.:

%%cache mycache.pkl var1 var2
var1 = 1
var2 = 2

When you execute this cell the first time, the code is executed, and the variables var1 and var2 are saved in mycache.pkl in the current directory along with the outputs. Rich display outputs are only saved if you use the development version of IPython. When you execute this cell again, the code is skipped, the variables are loaded from the file and injected into the namespace, and the outputs are restored in the notebook.

It saves all graphics, output produced, and all the variables specified automatically for you :)

  • Extremely useful, and easier to get working for me than %autoreload (my other way of hacking around changing modules but not wanting to reload data )
    – ijoseph
    Jun 15, 2018 at 20:59
  • 3
    ipycache seems to need a lot of love. Warnings galore, and last update May 2016.
    – Tom Hale
    Mar 20, 2019 at 7:23
  • 1
    Damn, it used to be low maintenance :S I guess things change as python versions progress... Still have some good memories, and the best solution I've found so far, would be great to find something better/more active
    – ntg
    Mar 20, 2019 at 10:24
  • What is the difference with %store?
    – BND
    Apr 17, 2019 at 12:26
  • 3
    ipycache is no longer maintained, do you know another tool? Feb 4, 2020 at 13:22

Use the cache magic.

%cache myVar = someSlowCalculation(some, "parameters")

This will calculate someSlowCalculation(some, "parameters") once. And in subsequent calls it restores myVar from storage.


Under the hood it does pretty much the same as the accepted answer.

  • 1
    When does a cached variable get invalidated? Ideally it would invalidated when the variables that it depends upon changes but that seems kind clever.
    – Att Righ
    Feb 8, 2022 at 12:27
  • 1
    per default it changes when the string right of the "=" changes. So it changes when method or its direct parameters change, but it does not look into the methods or the values of the parameters
    – wotanii
    Feb 9, 2022 at 7:01
  • 1
    Oooh, that sounds likely precisely what I want.
    – Att Righ
    Feb 9, 2022 at 15:30
  • Hmm there was no cache invalidation when I just tested this.
    – Att Righ
    Feb 25, 2022 at 9:47

Can you give an example of what you are trying to do? When I run something in an IPython Notebook that is expensive I almost always write it to disk afterword. For example, if my data is a list of JSON object, I write it to disk as line separated JSON formatted strings:

with open('path_to_file.json', 'a') as file:
    for item in data: 
        line = json.dumps(item)
        file.write(line + '\n')

You can then read back in the data the same way:

data = []
with open('path_to_file.json', 'a') as file:
    for line in file: 
        data_item = json.loads(line)

I think this is a good practice generally speaking because it provides you a backup. You can also use pickle for the same thing. If your data is really big you can actually gzip.open to directly write to a zip file.


To save a scikit learn model to disk use joblib.pickle.

from sklearn.cluster import KMeans

km = KMeans(n_clusters=num_clusters)

from sklearn.externals import joblib
# dump to pickle
joblib.dump(km, 'model.pkl')

# and reload from pickle
km = joblib.load('model.pkl')
  • I tried applying machine learning models to datasets. For example, I import some data (a few hundred MB) by pandas, and then train and test two models by scikit-learn. I want to "cache" all intermediate transformed DataFrame, as well as the trained models. So I can "carry on" experiments on the intermediate DataFrame without reading from the ground.
    – Zelong
    Sep 5, 2015 at 9:51
  • @zelong ok, you should use joblib to pickle your sklearn models. See my edit above. And to write your dataframes to disk just use dataframe.to_csv('yourfile.csv)
    – brandomr
    Sep 5, 2015 at 21:03
  • Thanks a lot. The pickling of scikit-learn model looks quite good. I tried quite a few wrangling with DataFrames and it seems demanding to save a bunch of intermediate DataFrame to csv files. But it seems IPython has not provide a counterpart of RData cache, which put everything in a single cube.
    – Zelong
    Sep 5, 2015 at 21:44
  • I removed the file.close() calls, because with closes files for you. Oct 25, 2017 at 9:42
  • Also: since data is a "list", one could more simply do json.dump(data, file), without any loop. And similarly json.load(file). Oct 25, 2017 at 9:49

If you don't want to install any additional packages, there is a very simple solution using python's builtin shelve module, which acts like a persistent dict object. Since the shelve lives in a file on disk, it also survives restarts. It can't be accessed from multiple kernels at once though, because the underlying DBM database does not support concurrent access.

We can define a simple wrapper function that will fetch the result of an expensive computation from the shelve if it is found:

# Notebook cell to define the cache function
import shelve
_cache_database_filename = 'MyNotebookName.ipynb.cacheDB'

def cache(variable_name: str, get_value_lazy: callable):
    global _cache_database, _cache_database_filename
    if '_cache_database' not in globals():
        _cache_database = shelve.open(_cache_database_filename)
    if variable_name not in _cache_database:
        _cache_database[variable_name] = get_value_lazy()  # Not in cache, compute value
    return _cache_database[variable_name]

To use it, you wrap your long-running calculations with cache('variable_name', lambda: ...). The lambda is there so that the calculation is only executed lazily if the requested variable is not in the cache. Otherwise it would be computed before calling cache, which defeats the purpose.

# Notebook cell that performs some long calculation:
def expensive_calculation(x): return len(str(x ** x))

# Instead of:
#my_result = expensive_calculation(100000)
# You write:
my_result = cache('my_result', lambda: expensive_calculation(100000))

The first time you run this cell, it will take several seconds to run expensive_calculation(100000) and save the result to the file MyNotebookName.ipynb.cacheDB. When you re-run the cell, even after restarting the Jupyter kernel, it will load the result from the cache database:

In [2]: def expensive_calculation(x): return len(str(x ** x))

In [3]: %time a = cache('a', lambda: expensive_calculation(100000))
CPU times: user 3.64 s, sys: 9.48 ms, total: 3.65 s
Wall time: 3.69 s

In [4]: %time a = cache('a', lambda: expensive_calculation(100000))
CPU times: user 58 µs, sys: 0 ns, total: 58 µs
Wall time: 65.8 µs

In [5]: del _cache_database['a']  # Remove an entry from cache

In [6]: %time a = cache('a', lambda: expensive_calculation(100000))
CPU times: user 3.67 s, sys: 0 ns, total: 3.67 s
Wall time: 3.66 s

In [7]: quit

Starting a new ipython session:

In [1]: def cache...

In [2]: def expensive_calculation(x): return len(str(x ** x))

In [3]: %time a = cache('a', lambda: expensive_calculation(100000))
CPU times: user 2.63 ms, sys: 617 µs, total: 3.24 ms
Wall time: 3.25 ms

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