I'm going to be running a large number of simulations producing a large amount of data that needs to be stored and accessed again later. Output data from my simulation program is written to text files (one per simulation). I plan on writing a Python program that reads these text files and then stores the data in a format more convenient for analyzing later. After quite a bit of searching, I think I'm suffering from information overload, so I'm putting this question to stackoverflow for some advice. Here are the details:

My data will basically take the form of a multidimensional array where each entry will look something like this:

data[ stringArg1, stringArg2, stringArg3, stringArg4, intArg1 ] = [ floatResult01, floatResult02, ..., floatResult12 ]

Each argument has roughly the following numbers of potential values:

stringArg1: 50

stringArg2: 20

stringArg3: 6

stringArg4: 24

intArg1: 10,000

Note, however, that the data set will be sparse. For example, for a given value of stringArg1, only about 16 values of stringArg2 will be filled in. Also, for a given combination of (stringArg1, stringArg2) roughly 5000 values of intArg1 will be filled in. The 3rd and 4th string arguments are always completely filled.

So, with these numbers my array will have roughly 50*16*6*24*5000 = 576,000,000 result lists.

I'm looking for the best way to store this array such that I can save it and reopen it later to either add more data, update existing data, or query existing data for analysis. Thus far I've looked into three different approaches:

1.) a relational database

2.) PyTables

3.) Python dictionary that uses tuples as the dictionary keys (using pickle to save & reload)

There's one issue I run into in all three approaches, I always end up storing every tuple combination of (stringArg1, stringArg2, stringArg3, stringArg4, intArg1), either as a field in a table, or as the keys in the Python dictionary. From my (possibly naive) point of view, it seems like this shouldn't be necessary. If these were all integer arguments then they would just form the address of each data entry in the array, and there wouldn't be any need to store all the potential address combinations in a separate field. For example, if I had a 2x2 array = [[100, 200] , [300, 400]] you would retrieve values by asking for the value at an address array[0][1]. You wouldn't need to store all the possible address tuples (0,0) (0,1) (1,0) (1,1) somewhere else. So I'm hoping to find a way around this.

What I would love to be able to do is define a table in PyTables, where cells in this first table contain other tables. For example, the top-level tables would have two columns. Entries in the first column would be the possible values of stringArg1. Each entry in the second column would be a table. These sub-tables would then have two columns, the first being all the possible values of stringArg2, the second being another column of sub-sub-tables...

That kind of solution would be straightforward to browse and query (particularly if I could use ViTables to browse the data). The problem is PyTables doesn't seem to support having the cells of one table contain other tables. So I seem to have hit a dead end there.

I've been reading up on data warehousing and the star schema approach, but it still seems like your fact table would need to contain tuples of every possible argument combination.

Okay, so that's pretty much where I am. Any and all advice would be very much appreciated. At this point I've been searching around so much that my brain hurts. I figure it's time to ask the experts. Thanks in advance to anyone and everyone who replies.

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I'm not clear on what you're wanting to store here. Are you wanting to store not only your current data set, but also the constraints as to which combinations of values in the different fields are valid? Until your data model is clear, your chances of successfully implementing an efficient storage solution are limited. –  ncoghlan Feb 21 '11 at 3:31

Why not using a big table for keep all the 500 millions of entries? If you use on-the-flight compression (Blosc compressor recommended here), most of the duplicated entries will be deduped, so the overhead in storage is kept under a minimum. I'd recommend give this a try; sometimes the simple solution works best ;-)

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Good point. Simple is good if it works. Do you have any examples of how to use Blosc on a PyTables table? I'm fairly new to PyTables and I haven't been able to find an example anywhere (neither on the Blosc website nor PyTables). I did, however, test out my scheme above using a single table and only 50 values of the integer variable. With that scheme the .h5 file PyTables created was 450 MB! Cleary I'll need compression if this is going to scale to my full set of data. Any help on using Blosc would be much appreciated. –  dbb Mar 2 '11 at 6:39

Is there a reason the basic 6 table approach doesn't apply?

i.e. Tables 1-5 would be single column tables defining the valid values for each of the fields, and then the final table would be a 5 column table defining the entries that actually exist.

Alternatively, if every value always exists for the 3rd and 4th string values as you describe, the 6th table could just consist of 3 columns (string1, string2, int1) and you generate the combinations with string3 and string4 dynamically via a Cartesian join.

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I'm not entirely sure of what you're trying to do here, but it looks like you trying to create a (potentially) sparse multidimensional array. So I wont go into details for solving your specific problem, but the best package I know that deals with this is Numpy Numpy. Numpy can

be used as an efficient multi-dimensional container of generic data. Arbitrary data-types can be defined. This allows NumPy to seamlessly and speedily integrate with a wide variety of databases.

I've used Numpy many times for simulation data processing and it provides many useful tools including easy file storage/access.

Hopefully you'll find something in it's very easy to read documentation:

Numpy Documentation with Examples

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