From what I know this would be the use case that Dask seems to solve.
I think this blog post can help: https://www.continuum.io/content/xray-dask-out-core-labeled-arrays-python Notice that I haven't used any of these projects myself. On Thu, Jan 14, 2016 at 11:48 AM, Francesc Alted <faltet@gmail.com> wrote:
Well, maybe something like a simple class emulating a dictionary that stores a key-value on disk would be more than enough. Then you can use whatever persistence layer that you want (even HDF5, but not necessarily).
As a demonstration I did a quick and dirty implementation for such a persistent key-store thing ( https://gist.github.com/FrancescAlted/8e87c8762a49cf5fc897). On it, the KeyStore class (less than 40 lines long) is responsible for storing the value (2 arrays) into a key (a directory). As I am quite a big fan of compression, I implemented a couple of serialization flavors: one using the .npz format (so no other dependencies than NumPy are needed) and the other using the ctable object from the bcolz package (bcolz.blosc.org). Here are some performance numbers:
python key-store.py -f numpy -d __test -l 0 ########## Checking method: numpy (via .npz files) ############ Building database. Wait please... Time ( creation) --> 1.906 Retrieving 100 keys in arbitrary order... Time ( query) --> 0.191 Number of elements out of getitem: 10518976 faltet@faltet-Latitude-E6430:~/blosc/bcolz$ du -sh __test
75M __test
So, with the NPZ format we can deal with the 75 MB quite easily. But NPZ can compress data as well, so let's see how it goes:
$ python key-store.py -f numpy -d __test -l 9 ########## Checking method: numpy (via .npz files) ############ Building database. Wait please... Time ( creation) --> 6.636 Retrieving 100 keys in arbitrary order... Time ( query) --> 0.384 Number of elements out of getitem: 10518976 faltet@faltet-Latitude-E6430:~/blosc/bcolz$ du -sh __test 28M __test
Ok, in this case we have got almost a 3x compression ratio, which is not bad. However, the performance has degraded a lot. Let's use now bcolz. First in non-compressed mode:
$ python key-store.py -f bcolz -d __test -l 0 ########## Checking method: bcolz (via ctable(clevel=0, cname='blosclz') ############ Building database. Wait please... Time ( creation) --> 0.479 Retrieving 100 keys in arbitrary order... Time ( query) --> 0.103 Number of elements out of getitem: 10518976 faltet@faltet-Latitude-E6430:~/blosc/bcolz$ du -sh __test 82M __test
Without compression, bcolz takes a bit more (~10%) space than NPZ. However, bcolz is actually meant to be used with compression on by default:
$ python key-store.py -f bcolz -d __test -l 9 ########## Checking method: bcolz (via ctable(clevel=9, cname='blosclz') ############ Building database. Wait please... Time ( creation) --> 0.487 Retrieving 100 keys in arbitrary order... Time ( query) --> 0.98 Number of elements out of getitem: 10518976 faltet@faltet-Latitude-E6430:~/blosc/bcolz$ du -sh __test 29M __test
So, the final disk usage is quite similar to NPZ, but it can store and retrieve lots faster. Also, the data decompression speed is on par to using non-compression. This is because bcolz uses Blosc behind the scenes, which is much faster than zlib (used by NPZ) --and sometimes faster than a memcpy(). However, even we are doing I/O against the disk, this dataset is so small that fits in the OS filesystem cache, so the benchmark is actually checking I/O at memory speeds, not disk speeds.
In order to do a more real-life comparison, let's use a dataset that is much larger than the amount of memory in my laptop (8 GB):
$ PYTHONPATH=. python key-store.py -f bcolz -m 1000000 -k 5000 -d /media/faltet/docker/__test -l 0 ########## Checking method: bcolz (via ctable(clevel=0, cname='blosclz') ############ Building database. Wait please... Time ( creation) --> 133.650 Retrieving 100 keys in arbitrary order... Time ( query) --> 2.881 Number of elements out of getitem: 91907396 faltet@faltet-Latitude-E6430:~/blosc/bcolz$ du -sh /media/faltet/docker/__test
39G /media/faltet/docker/__test
and now, with compression on:
$ PYTHONPATH=. python key-store.py -f bcolz -m 1000000 -k 5000 -d /media/faltet/docker/__test -l 9 ########## Checking method: bcolz (via ctable(clevel=9, cname='blosclz') ############ Building database. Wait please... Time ( creation) --> 145.633 Retrieving 100 keys in arbitrary order... Time ( query) --> 1.339 Number of elements out of getitem: 91907396 faltet@faltet-Latitude-E6430:~/blosc/bcolz$ du -sh /media/faltet/docker/__test
12G /media/faltet/docker/__test
So, we are still seeing the 3x compression ratio. But the interesting thing here is that the compressed version works a 50% faster than the uncompressed one (13 ms/query vs 29 ms/query). In this case I was using a SSD (hence the low query times), so the compression advantage is even more noticeable than when using memory as above (as expected).
But anyway, this is just a demonstration that you don't need heavy tools to achieve what you want. And as a corollary, (fast) compressors can save you not only storage, but processing time too.
Francesc
2016-01-14 11:19 GMT+01:00 Nathaniel Smith <njs@pobox.com>:
I'd try storing the data in hdf5 (probably via h5py, which is a more basic interface without all the bells-and-whistles that pytables adds), though any method you use is going to be limited by the need to do a seek before each read. Storing the data on SSD will probably help a lot if you can afford it for your data size.
Hi,
I have a very large dictionary that must be shared across processes and does not fit in RAM. I need access to this object to be fast. The key is an integer ID and the value is a list containing two elements, both of them numpy arrays (one has ints, the other has floats). The key is sequential, starts at 0, and there are no gaps, so the “outer” layer of this data structure could really just be a list with the key actually being the index. The lengths of each pair of arrays may differ across keys.
For a visual:
{ key=0: [ numpy.array([1,8,15,…, 16000]), numpy.array([0.1,0.1,0.1,…,0.1]) ], key=1: [ numpy.array([5,6]), numpy.array([0.5,0.5]) ], … }
I’ve tried: - manager proxy objects, but the object was so big that low-level code threw an exception due to format and monkey-patching wasn’t successful. - Redis, which was far too slow due to setting up connections and data conversion etc. - Numpy rec arrays + memory mapping, but there is a restriction
On Thu, Jan 14, 2016 at 1:15 AM, Ryan R. Rosario <ryan@bytemining.com> wrote: that the numpy arrays in each “column” must be of fixed and same size.
- I looked at PyTables, which may be a solution, but seems to have a very steep learning curve. - I haven’t tried SQLite3, but I am worried about the time it takes to query the DB for a sequential ID, and then translate byte arrays.
Any ideas? I greatly appreciate any guidance you can provide.
Thanks, Ryan _______________________________________________ NumPy-Discussion mailing list NumPy-Discussion@scipy.org https://mail.scipy.org/mailman/listinfo/numpy-discussion
-- Nathaniel J. Smith -- http://vorpus.org _______________________________________________ NumPy-Discussion mailing list NumPy-Discussion@scipy.org https://mail.scipy.org/mailman/listinfo/numpy-discussion
-- Francesc Alted
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