I have a script that generates two-dimensional numpy arrays with dtype=float and shape on the order of (1e3, 1e6). Right now I'm using np.save and np.load to perform IO operations with the arrays. However, these functions take several seconds for each array. Are there faster methods for saving and loading the entire arrays (i.e., without making assumptions about their contents and reducing them)? I'm open to converting the arrays to another type before saving as long as the data are retained exactly.


For really big arrays, I've heard about several solutions, and they mostly on being lazy on the I/O :

  • NumPy.memmap, maps big arrays to binary form
    • Pros :
      • No dependency other than Numpy
      • Transparent replacement of ndarray (Any class accepting ndarray accepts memmap )
    • Cons :
      • Chunks of your array are limited to 2.5G
      • Still limited by Numpy throughput
  • Use Python bindings for HDF5, a bigdata-ready file format, like PyTables or h5py

    • Pros :
      • Format supports compression, indexing, and other super nice features
      • Apparently the ultimate PetaByte-large file format
    • Cons :
      • Learning curve of having a hierarchical format ?
      • Have to define what your performance needs are (see later)
  • Python's pickling system (out of the race, mentioned for Pythonicity rather than speed)

    • Pros:
      • It's Pythonic ! (haha)
      • Supports all sorts of objects
    • Cons:
      • Probably slower than others (because aimed at any objects not arrays)


From the docs of NumPy.memmap :

Create a memory-map to an array stored in a binary file on disk.

Memory-mapped files are used for accessing small segments of large files on disk, without reading the entire file into memory

The memmap object can be used anywhere an ndarray is accepted. Given any memmap fp , isinstance(fp, numpy.ndarray) returns True.

HDF5 arrays

From the h5py doc

Lets you store huge amounts of numerical data, and easily manipulate that data from NumPy. For example, you can slice into multi-terabyte datasets stored on disk, as if they were real NumPy arrays. Thousands of datasets can be stored in a single file, categorized and tagged however you want.

The format supports compression of data in various ways (more bits loaded for same I/O read), but this means that the data becomes less easy to query individually, but in your case (purely loading / dumping arrays) it might be efficient

  • did you do the profiling? how was h5py? Im having some trouble, gets considerably slower when having thousands of datasets in the same file... – fr_andres Jul 24 '17 at 15:27
  • i heard hdf5 doesnt support threading/processing/celery, how do you get around that – PirateApp Apr 30 '18 at 13:45
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    @PirateApp Threading example from h5py shows otherwise? Do open up a separate question if you need additional specific help – Jiby May 2 '18 at 19:47

Here is a comparison with PyTables.

I cannot get up to (int(1e3), int(1e6) due to memory restrictions. Therefore, I used a smaller array:

data = np.random.random((int(1e3), int(1e5)))

NumPy save:

%timeit np.save('array.npy', data)
1 loops, best of 3: 4.26 s per loop

NumPy load:

%timeit data2 = np.load('array.npy')
1 loops, best of 3: 3.43 s per loop

PyTables writing:

with tables.open_file('array.tbl', 'w') as h5_file:
    h5_file.create_array('/', 'data', data)

1 loops, best of 3: 4.16 s per loop

PyTables reading:

 with tables.open_file('array.tbl', 'r') as h5_file:
      data2 = h5_file.root.data.read()

 1 loops, best of 3: 3.51 s per loop

The numbers are very similar. So no real gain wit PyTables here. But we are pretty close to the maximum writing and reading rate of my SSD.


Maximum write speed: 241.6 MB/s
PyTables write speed: 183.4 MB/s


Maximum read speed: 250.2
PyTables read speed: 217.4

Compression does not really help due to the randomness of the data:

FILTERS = tables.Filters(complib='blosc', complevel=5)
with tables.open_file('array.tbl', mode='w', filters=FILTERS) as h5_file:
    h5_file.create_carray('/', 'data', obj=data)
1 loops, best of 3: 4.08 s per loop

Reading of the compressed data becomes a bit slower:

with tables.open_file('array.tbl', 'r') as h5_file:
    data2 = h5_file.root.data.read()

1 loops, best of 3: 4.01 s per loop

This is different for regular data:

 reg_data = np.ones((int(1e3), int(1e5)))

Writing is significantly faster:

FILTERS = tables.Filters(complib='blosc', complevel=5)
with tables.open_file('array.tbl', mode='w', filters=FILTERS) as h5_file:
    h5_file.create_carray('/', 'reg_data', obj=reg_data)

1 loops, best of 3: 849 ms per loop

The same holds true for reading:

with tables.open_file('array.tbl', 'r') as h5_file:
    reg_data2 = h5_file.root.reg_data.read()

1 loops, best of 3: 1.7 s per loop

Conclusion: The more regular your data the faster it should get using PyTables.


According to my experience, np.save()&np.load() is the fastest solution when trasfering data between hard disk and memory so far. I've heavily relied my data loading on database and HDFS system before I realized this conclusion. My tests shows that: The database data loading(from hard disk to memory) bandwidth could be around 50 MBps(Byets/Second), but the np.load() bandwidth is almost same as my hard disk maximum bandwidth: 2GBps(Byets/Second). Both test environments use the simplest data structure.

And I don't think it's a problem to use several seconds to loading an array with shape: (1e3, 1e6). E.g. Your array shape is (1000, 1000000), its data type is float128, then the pure data size is (128/8)*1000*1,000,000=16,000,000,000=16GBytes and if it takes 4 seconds, Then your data loading bandwidth is 16GBytes/4Seconds = 4GBps. SATA3 maximum bandwidth is 600MBps=0.6GBps, your data loading bandwidth is already 6 times of it, your data loading performance almost could compete with DDR's maximum bandwidth, what else do you want?

So my final conclusion is:

Don't use python's Pickle, don't use any database, don't use any big data system to store your data into hard disk, if you could use np.save() and np.load(). These two functions are the fastest solution to transfer data between harddisk and memory so far.

I've also tested the HDF5 , and found that it's much slower than np.load() and np.save(), so use np.save()&np.load() if you've enough DDR memory in your platfrom.

  • 1
    If you can't reach reach the maximum bandwith of your storage device using HDF5 you have usualy made something wrong. And there are many things that can go wrong. (chunk-cache,chunkshape, fancy indexing,...) – max9111 Mar 1 '18 at 17:39
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    Try for example this stackoverflow.com/a/48997927/4045774 with and without compression (the compression limits at about 500-800 MB/s. For well compressible data you can get a lot more throuput with HDF 5 on a HDD or even a SATA3 SSD. But the main advantage is reading or writing parts of array along abitrary axis at sequential IO-Speed. If IO-speed realy matters, it is also likely that the array is bigger than the RAM... – max9111 Mar 1 '18 at 20:15
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    @ClockZHONG, thanks for your post, how about DataFrames? – Warren Oct 30 '18 at 10:21
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    What if you want random access of the array values on disk? I'm assuming you would have to go to HDF5 for that use case? – Duane Dec 18 '18 at 1:25
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    @Duane no, It's impossible, if you want to random access a small part of data from a very very big number, our only choices are database, HDF5 or some other mechanism which could support us to randomly access harddisk. I suggest to use np.load() only when we have enough DDR memory space and our data is not so huge, at least our data could be put into our memory space. – Clock ZHONG Dec 24 '18 at 14:56

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