marisa-trie ===========

Static memory-efficient Trie-like structures for Python (2.x and 3.x).

String data in a MARISA-trie may take up to 50x-100x less memory than in a standard Python dict; the raw lookup speed is comparable; trie also provides fast advanced methods like prefix search.

Based on marisa-trie C++ library.

pip install marisa-trie

There are several Trie classes in this package:

• marisa_trie.Trie - read-only trie-based data structure that maps unicode keys to auto-generated unique IDs;
• marisa_trie.RecordTrie - read-only trie-based data structure that maps unicode keys to lists of data tuples. All tuples must be of the same format (the data is packed using python struct module).
• marisa_trie.BytesTrie - read-only Trie that maps unicode keys to lists of bytes objects.

Create a new trie:

>>> import marisa_trie
>>> trie = marisa_trie.Trie([u'key1', u'key2', u'key12'])

Check if key is in trie:

>>> u'key1' in trie
True
>>> u'key20' in trie
False

Each key is assigned an unique ID from 0 to (n - 1), where n is the number of keys:

>>> trie.key_id(u'key2')
1
>>> trie[u'key2']  # alternative syntax
1

Note that you can't assign a value to a marisa_trie.Trie key, but can use the returned ID to store a value in a separate data structure (e.g. in a python list or numpy array).

Key can be reconstructed from the ID:

>>> trie.restore_key(1)
u'key2'

Find all prefixes of a given key:

>>> trie.prefixes(u'key12')
[u'key1', u'key12']

There is also a generator version of .prefixes method called .iter_prefixes.

Find all keys from this trie that starts with a given prefix:

>> trie.keys(u'key1')
[u'key1', u'key12']

(iterator version .iterkeys(prefix) is also available).

Use items() method to return all (key, ID) pairs:

>>> trie.items()
[(u'key1', 0), (u'key12', 2), (u'key2', 1)]

Filter them by prefix:

>>> trie.items(u'key1')
[(u'key1', 0), (u'key12', 2)]

(iterator version .iteritems(prefix) is also available).

Create a new trie:

>>> keys = [u'foo', u'bar', u'foobar', u'foo']
>>> values = [(1, 2), (2, 1), (3, 3), (2, 1)]
>>> fmt = "<HH"   # a tuple with 2 short integers
>>> trie = marisa_trie.RecordTrie(fmt, zip(keys, values))

Trie initial data must be an iterable of tuples (unicode_key, data_tuple). Data tuples will be converted to bytes with struct.pack(fmt, *data_tuple).

Take a look at http://docs.python.org/library/struct.html#format-strings for the format string specification.

Duplicate keys are allowed.

Check if key is in trie:

>>> u'foo' in trie
True
>>> u'spam' in trie
False

Get a values list:

>>> trie[u'bar']
[(2, 1)]
>>> trie[u'foo']
[(1, 2), (2, 1)]
>>> trie.get(u'bar', 123)
[(2, 1)]
>>> trie.get(u'BAAR', 123) # default value
123

Find all prefixes of a given key:

>>> trie.prefixes(u'foobarz')
[u'foo', u'foobar']

Test whether some key begins with a given prefix:

>>> trie.has_keys_with_prefix(u'fo')
True
>>> trie.has_keys_with_prefix(u'go')
False

Find all keys from this trie that starts with a given prefix:

>> trie.keys(u'fo')
[u'foo', u'foo', u'foobar']

Find all items from this trie that starts with a given prefix:

>> trie.items(u'fo')
[(u'foo', (1, 2)), (u'foo', (2, 1), (u'foobar', (3, 3))]

BytesTrie is similar to RecordTrie, but the values are raw bytes, not tuples:

>>> keys = [u'foo', u'bar', u'foobar', u'foo']
>>> values = [b'foo-value', b'bar-value', b'foobar-value', b'foo-value2']
>>> trie = marisa_trie.BytesTrie(zip(keys, values))
>>> trie[u'bar']
[b'bar-value']

Trie objects supports saving/loading, pickling/unpickling and memory mapped I/O.

Write trie to a stream:

>>> with open('my_trie.marisa', 'w') as f:
...     trie.write(f)

Save trie to a file:

>>> trie.save('my_trie_copy.marisa')

Read trie from stream:

>>> trie2 = marisa_trie.Trie()
>>> with open('my_trie.marisa', 'r') as f:
...     trie.read(f)

Load trie from file:

>>> trie2.load('my_trie.marisa')

Trie objects are picklable:

>>> import pickle
>>> data = pickle.dumps(trie)
>>> trie3 = pickle.loads(data)

You may also build a trie using marisa-build command-line utility (provided by underlying C++ library; it should be downloaded and compiled separately) and then load the trie from the resulting file using .load() method.

It is possible to use memory mapped file as data source:

>>> trie = marisa_trie.RecordTrie(fmt).mmap('my_record_trie.marisa')

This way the whole dictionary won't be loaded to memory; memory mapped I/O is an easy way to share dictionary data among processes.

marisa-trie C++ library provides some configuration options for trie storage; check http://marisa-trie.googlecode.com/svn/trunk/docs/readme.en.html page (scroll down to "Enumeration Constants" section) to get an idea.

These options are exposed as order, num_tries, cache_size and binary keyword arguments for trie constructors.

For example, set order to marisa_trie.LABEL_ORDER in order to make trie functions return results in alphabetical oder:

>>> trie = marisa_trie.RecordTrie(fmt, data, order=marisa_trie.LABEL_ORDER)

Note that two tries constructed from identical data but with different order arguments will compare unequal:

>>> t1 = marisa_trie.Trie(order=marisa_trie.LABEL_ORDER)
>>> t2 = marisa_trie.Trie(order=marisa_trie.WEIGHT_ORDER)
>>> t1 == t2
False

My quick tests show that memory usage is quite decent. For a list of 3000000 (3 million) Russian words memory consumption with different data structures (under Python 2.7):

• dict(unicode words -> word lenghts): about 600M
• list(unicode words) : about 300M
• BaseTrie from datrie library: about 70M
• marisa_trie.RecordTrie : 11M
• marisa_trie.Trie: 7M

Benchmark results (100k unicode words, integer values (lenghts of the words), Python 3.2, macbook air i5 1.8 Ghz):

dict building                     2.919M words/sec
Trie building                     0.394M words/sec
BytesTrie building                0.355M words/sec
RecordTrie building               0.354M words/sec

dict __getitem__ (hits)           8.239M ops/sec
Trie __getitem__ (hits)           not supported
BytesTrie __getitem__ (hits)      0.498M ops/sec
RecordTrie __getitem__ (hits)     0.404M ops/sec

dict get() (hits)                 4.410M ops/sec
Trie get() (hits)                 not supported
BytesTrie get() (hits)            0.458M ops/sec
RecordTrie get() (hits)           0.364M ops/sec
dict get() (misses)               4.869M ops/sec
Trie get() (misses)               not supported
BytesTrie get() (misses)          0.849M ops/sec
RecordTrie get() (misses)         0.816M ops/sec

dict __contains__ (hits)          8.053M ops/sec
Trie __contains__ (hits)          1.018M ops/sec
BytesTrie __contains__ (hits)     0.605M ops/sec
RecordTrie __contains__ (hits)    0.618M ops/sec
dict __contains__ (misses)        6.489M ops/sec
Trie __contains__ (misses)        2.047M ops/sec
BytesTrie __contains__ (misses)   1.079M ops/sec
RecordTrie __contains__ (misses)  1.123M ops/sec

dict items()                      57.248 ops/sec
Trie items()                      not supported
BytesTrie items()                 11.691 ops/sec
RecordTrie items()                8.369 ops/sec

dict keys()                       217.920 ops/sec
Trie keys()                       19.589 ops/sec
BytesTrie keys()                  14.849 ops/sec
RecordTrie keys()                 15.369 ops/sec

Trie.prefixes (hits)              0.594M ops/sec
Trie.prefixes (mixed)             1.874M ops/sec
Trie.prefixes (misses)            1.447M ops/sec
RecordTrie.prefixes (hits)        0.103M ops/sec
RecordTrie.prefixes (mixed)       0.458M ops/sec
RecordTrie.prefixes (misses)      0.164M ops/sec
Trie.iter_prefixes (hits)         0.588M ops/sec
Trie.iter_prefixes (mixed)        1.470M ops/sec
Trie.iter_prefixes (misses)       1.170M ops/sec

Trie.keys(prefix="xxx"), avg_len(res)==415                   5.044K ops/sec
Trie.keys(prefix="xxxxx"), avg_len(res)==17                  89.363K ops/sec
Trie.keys(prefix="xxxxxxxx"), avg_len(res)==3                258.732K ops/sec
Trie.keys(prefix="xxxxx..xx"), avg_len(res)==1.4             293.199K ops/sec
Trie.keys(prefix="xxx"), NON_EXISTING                        1169.524K ops/sec

RecordTrie.keys(prefix="xxx"), avg_len(res)==415             3.836K ops/sec
RecordTrie.keys(prefix="xxxxx"), avg_len(res)==17            73.591K ops/sec
RecordTrie.keys(prefix="xxxxxxxx"), avg_len(res)==3          229.515K ops/sec
RecordTrie.keys(prefix="xxxxx..xx"), avg_len(res)==1.4       269.228K ops/sec
RecordTrie.keys(prefix="xxx"), NON_EXISTING                  1071.433K ops/sec

Tries from marisa_trie are static and uses less memory, tries from datrie are faster and can be updated.

You may also give DAWG a try - it is usually faster than marisa-trie and sometimes can use less memory (depending on data).

Please take this benchmark results with a grain of salt; this is a very simple benchmark on a single data set.

• The library is not tested with mingw32 compiler;
• .prefixes() method of BytesTrie and RecordTrie is quite slow and doesn't have iterator counterpart;
• read() and write() methods don't work with file-like objects (they work only with real files; pickling works fine for file-like objects);
• there are keys() and items() methods but no values() method.

Contributions are welcome!

Development happens at github: https://github.com/kmike/marisa-trie

Feel free to submit ideas, bug reports and pull requests.

If you found a bug in a C++ part please report it to the original bug tracker.

There are 4 folders in repository:

• bench - benchmarks & benchmark data;
• lib - original unmodified marisa-trie C++ library which is bundled for easier distribution; if something is have to be fixed in this library consider fixing it in the original repo ;
• src - wrapper code; src/marisa_trie.pyx is a wrapper implementation; src/*.pxd files are Cython headers for corresponding C++ headers; src/*.cpp files are the pre-built extension code and shouldn't be modified directly (they should be updated via update_cpp.sh script).
• tests - the test suite.

Make sure tox is installed and run

$ tox

from the source checkout. Tests should pass under python 2.6, 2.7, 3.2, 3.3 and 3.4.

In order to run benchmarks, type

$ tox -c bench.ini

• Mikhail Korobov <[email protected]>
• Matt Hickford
• Sergei Lebedev <[email protected]>

This module is based on marisa-trie C++ library by Susumu Yata & contributors.

Wrapper code is licensed under MIT License. Bundled marisa-trie C++ library is dual-licensed under LGPL and BSD 2-clause license.