spaCy/spacy/lang.pyx

# cython: profile=True
# cython: embedsignature=True
"""Common classes and utilities across languages.

Provides the main implementation for the spacy tokenizer. Specific languages
subclass the Language class, over-writing the tokenization rules as necessary.
Special-case tokenization rules are read from data/<lang>/tokenization .
"""
from __future__ import unicode_literals

from libc.stdlib cimport calloc, free

import json
import random
from os import path

from .util import read_lang_data
from spacy.tokens import Tokens
from spacy.lexeme cimport LexemeC, lexeme_init
from murmurhash.mrmr cimport hash64


cdef class Language:
    """Base class for language-specific tokenizers.

    Most subclasses will override the _split or _split_one methods, which take
    a string of non-whitespace characters and output a list of strings.  This
    function is called by _tokenize, which sits behind a cache and turns the
    list of strings into Lexeme objects via the Lexicon. Most languages will not
    need to override _tokenize or tokenize.

    The language is supplied a list of boolean functions, used to compute flag
    features. These are passed to the language's Lexicon object.

    The language's name is used to look up default data-files, found in data/<name.
    """
    def __cinit__(self, name, string_features, flag_features):
        if flag_features is None:
            flag_features = []
        if string_features is None:
            string_features = []
        self.name = name
        self.cache.set_empty_key(0)
        self.cache_size = 0
        lang_data = read_lang_data(name)
        rules, words, probs, clusters, case_stats, tag_stats = lang_data
        self.lexicon = Lexicon(words, probs, clusters, case_stats, tag_stats,
                               string_features, flag_features)
        self._load_special_tokenization(rules)
        self.tokens_class = Tokens

    property nr_types:
        def __get__(self):
            """Return the number of lexical types in the vocabulary"""
            return self.lexicon.size

    cpdef Lexeme lookup(self, unicode string):
        """Retrieve (or create, if not found) a Lexeme for a string, and return it.
    
        Args:
            string (unicode): The string to be looked up. Must be unicode, not bytes.

        Returns:
            lexeme (Lexeme): A reference to a lexical type.
        """
        return self.lexicon.lookup(string)

    cpdef Tokens tokenize(self, unicode string):
        """Tokenize a string.

        The tokenization rules are defined in two places:

        * The data/<lang>/tokenization table, which handles special cases like contractions;
        * The appropriate :py:meth:`find_split` function, which is used to split
          off punctuation etc.

        Args:
            string (unicode): The string to be tokenized. 

        Returns:
            tokens (Tokens): A Tokens object, giving access to a sequence of LexIDs.
        """
        print repr(string)
        cdef size_t length = len(string)
        cdef Tokens tokens = self.tokens_class(length)
        if length == 0:
            return tokens

        cdef size_t start = 0
        cdef size_t i = 0
        cdef Py_UNICODE* characters = string
        cdef Py_UNICODE c
        for i in range(length):
            c = characters[i]
            if c == ' ' or c == '\n' or c == '\t':
                if start < i:
                    self._tokenize(tokens, &characters[start], i - start)
                start = i + 1
        i += 1
        if start < i:
            self._tokenize(tokens, &characters[start], i - start)
        return tokens

    cdef int _tokenize(self, Tokens tokens, Py_UNICODE* characters, size_t length) except -1:
        cdef uint64_t hashed = hash64(characters, length * sizeof(Py_UNICODE), 0)
        cdef LexList* node = <LexList*>self.cache[hashed]
        if node is not NULL:
            while node != NULL:
                tokens.push_back(node.lex)
                node = node.tail
            return 0
   
        node = <LexList*>calloc(1, sizeof(LexList))
        self.cache[hashed] = <size_t>node
        cdef size_t start = 0
        cdef size_t split = 0
        while start < length:
            split = self._split_one(&characters[start], length - start)
            node.lex = <LexemeC*>self.lexicon.get(&characters[start], split)
            tokens.push_back(node.lex)
            start += split
            if start >= length:
                break
            hashed = hash64(&characters[start], (length - start) * sizeof(Py_UNICODE), 0)
            node.tail = <LexList*>self.cache[hashed]
            if node.tail == NULL:
                node.tail = <LexList*>calloc(1, sizeof(LexList))
                self.cache[hashed] = <size_t>node.tail
                node = node.tail
            else:
                node = node.tail
                while node != NULL:
                    tokens.push_back(node.lex)
                    node = node.tail
                break

    cdef int _split_one(self, Py_UNICODE* characters, size_t length):
        return length

    def _load_special_tokenization(self, token_rules):
        '''Load special-case tokenization rules.

        Loads special-case tokenization rules into the Language.cache cache,
        read from data/<lang>/tokenization . The special cases are loaded before
        any language data is tokenized, giving these priority.  For instance,
        the English tokenization rules map "ain't" to ["are", "not"].

        Args:
            token_rules (list): A list of (chunk, tokens) pairs, where chunk is
                a string and tokens is a list of strings.
        '''
        cdef LexList* node
        cdef uint64_t hashed
        for string, substrings in token_rules:
            hashed = hash64(<Py_UNICODE*>string, len(string) * sizeof(Py_UNICODE), 0)
            node = <LexList*>calloc(1, sizeof(LexList))
            self.cache[hashed] = <size_t>node
            for substring in substrings[:-1]:
                node.lex = <LexemeC*>self.lexicon.get(<Py_UNICODE*>substring, len(substring))
                node.tail = <LexList*>calloc(1, sizeof(LexList))
                node = node.tail
            node.lex = <LexemeC*>self.lexicon.get(<Py_UNICODE*>substrings[-1], len(substrings[-1]))
 

cdef class Lexicon:
    def __cinit__(self, words, probs, clusters, case_stats, tag_stats,
                  string_features, flag_features):
        self._flag_features = flag_features
        self._string_features = string_features
        self._dict.set_empty_key(0)
        self.size = 0
        cdef Lexeme word
        for string in words:
            prob = probs.get(string, 0.0)
            cluster = clusters.get(string, 0.0)
            cases = case_stats.get(string, {})
            tags = tag_stats.get(string, {})
            views = [string_view(string, prob, cluster, cases, tags)
                     for string_view in self._string_features]
            flags = set()
            for i, flag_feature in enumerate(self._flag_features):
                if flag_feature(string, prob, cluster, cases, tags):
                    flags.add(i)
            lexeme = lexeme_init(string, prob, cluster, views, flags)
            self._dict[string] = <size_t>lexeme
            self.size += 1

    cdef size_t get(self, Py_UNICODE* characters, size_t length):
        cdef uint64_t hashed = hash64(characters, length * sizeof(Py_UNICODE), 0)
        cdef LexemeC* lexeme = <LexemeC*>self._dict[hashed]
        if lexeme != NULL:
            return <size_t>lexeme
        
        cdef unicode string = characters[:length]
        views = [string_view(string, 0.0, 0, {}, {})
                 for string_view in self._string_features]
        flags = set()
        for i, flag_feature in enumerate(self._flag_features):
            if flag_feature(string, 0.0, {}, {}):
                flags.add(i)
 
        lexeme = lexeme_init(string, 0, 0, views, flags)
        self._dict[hashed] = <size_t>lexeme
        self.size += 1
        return <size_t>lexeme

    cpdef Lexeme lookup(self, unicode string):
        """Retrieve (or create, if not found) a Lexeme for a string, and return it.
    
        Args
            string (unicode):  The string to be looked up. Must be unicode, not bytes.

        Returns:
            lexeme (Lexeme): A reference to a lexical type.
        """
        cdef size_t lexeme = self.get(<Py_UNICODE*>string, len(string))
        return Lexeme(lexeme)
* Fixed major efficiency problem, from not quite grokking pass by reference in cython c++ 2014-07-07 09:36:43 +04:00			`# cython: profile=True`
* Broken version being refactored for docs 2014-08-20 15:39:39 +04:00			`# cython: embedsignature=True`
			`"""Common classes and utilities across languages.`

			`Provides the main implementation for the spacy tokenizer. Specific languages`
			`subclass the Language class, over-writing the tokenization rules as necessary.`
			`Special-case tokenization rules are read from data/<lang>/tokenization .`
			`"""`
* Initial commit. Tests passing for punctuation handling. Need contractions, file transport, tokenize function, etc. 2014-07-05 22:51:42 +04:00			`from __future__ import unicode_literals`
* Reorganized, moving language-independent stuff to spacy. The functions in spacy ask for the dictionaries and split function on input, but the language-specific modules are curried versions that use the globals 2014-07-07 06:21:06 +04:00
* Switch to dynamically allocating array, based on the document length 2014-07-07 10:05:29 +04:00			`from libc.stdlib cimport calloc, free`

* Refactoring with Lexeme as a class now compiles. Basic design seems to work 2014-08-27 19:15:39 +04:00			`import json`
* Improve cache mechanism by including a random element depending on the size of the cache. 2014-09-12 02:18:31 +04:00			`import random`
* Fixed major efficiency problem, from not quite grokking pass by reference in cython c++ 2014-07-07 09:36:43 +04:00			`from os import path`
* Progress to getting WordTree working. Tests pass, but so far it's slower. 2014-08-16 21:59:38 +04:00
* Redesign proceeding 2014-08-28 21:45:09 +04:00			`from .util import read_lang_data`
* Refactoring to use Tokens object 2014-09-10 20:11:13 +04:00			`from spacy.tokens import Tokens`
* Only store LexemeC structs in the vocabulary, transforming them to Lexeme objects for output. Moving away from Lexeme objects for Tokens soon. 2014-09-11 14:28:38 +04:00			`from spacy.lexeme cimport LexemeC, lexeme_init`
* Switch to 64 bit hashes, for better reliability 2014-09-12 04:04:47 +04:00			`from murmurhash.mrmr cimport hash64`
* Redesign proceeding 2014-08-28 21:45:09 +04:00
* Refactor for string view features. Working on setting up flags and enums. 2014-07-07 18:58:48 +04:00
* Reorganized code to accomodate Tokens class. Need string views before group_by and count_by can be done well. 2014-07-07 14:47:21 +04:00			`cdef class Language:`
* Redesign proceeding 2014-08-28 21:45:09 +04:00			`"""Base class for language-specific tokenizers.`

			`Most subclasses will override the _split or _split_one methods, which take`
			`a string of non-whitespace characters and output a list of strings. This`
			`function is called by _tokenize, which sits behind a cache and turns the`
			`list of strings into Lexeme objects via the Lexicon. Most languages will not`
			`need to override _tokenize or tokenize.`

			`The language is supplied a list of boolean functions, used to compute flag`
			`features. These are passed to the language's Lexicon object.`

			`The language's name is used to look up default data-files, found in data/<name.`
			`"""`
* Begin testing more functionality 2014-08-30 21:01:15 +04:00			`def __cinit__(self, name, string_features, flag_features):`
* Redesign proceeding 2014-08-28 21:45:09 +04:00			`if flag_features is None:`
			`flag_features = []`
			`if string_features is None:`
			`string_features = []`
* Reorganized code to accomodate Tokens class. Need string views before group_by and count_by can be done well. 2014-07-07 14:47:21 +04:00			`self.name = name`
* Restore dense_hash_map for cache dictionary. Seems to double efficiency 2014-09-12 04:23:51 +04:00			`self.cache.set_empty_key(0)`
			`self.cache_size = 0`
* Redesign proceeding 2014-08-28 21:45:09 +04:00			`lang_data = read_lang_data(name)`
			`rules, words, probs, clusters, case_stats, tag_stats = lang_data`
			`self.lexicon = Lexicon(words, probs, clusters, case_stats, tag_stats,`
			`string_features, flag_features)`
* Docs coming together 2014-08-29 03:59:23 +04:00			`self._load_special_tokenization(rules)`
* Refactor to use tokens class. 2014-09-10 20:27:44 +04:00			`self.tokens_class = Tokens`
* Refactoring to use Tokens object 2014-09-10 20:11:13 +04:00
			`property nr_types:`
			`def __get__(self):`
			`"""Return the number of lexical types in the vocabulary"""`
			`return self.lexicon.size`

			`cpdef Lexeme lookup(self, unicode string):`
			`"""Retrieve (or create, if not found) a Lexeme for a string, and return it.`

			`Args:`
			`string (unicode): The string to be looked up. Must be unicode, not bytes.`

			`Returns:`
			`lexeme (Lexeme): A reference to a lexical type.`
			`"""`
			`return self.lexicon.lookup(string)`
* Broken version being refactored for docs 2014-08-20 15:39:39 +04:00
* Switch to returning a Tokens object 2014-09-11 23:37:32 +04:00			`cpdef Tokens tokenize(self, unicode string):`
* Refactoring with Lexeme as a class now compiles. Basic design seems to work 2014-08-27 19:15:39 +04:00			`"""Tokenize a string.`

			`The tokenization rules are defined in two places:`
* Broken version being refactored for docs 2014-08-20 15:39:39 +04:00
* Refactoring with Lexeme as a class now compiles. Basic design seems to work 2014-08-27 19:15:39 +04:00			`* The data/<lang>/tokenization table, which handles special cases like contractions;`
			* The appropriate :py:meth:`find_split` function, which is used to split
			`off punctuation etc.`
* Reorganized code to accomodate Tokens class. Need string views before group_by and count_by can be done well. 2014-07-07 14:47:21 +04:00
* Broken version being refactored for docs 2014-08-20 15:39:39 +04:00			`Args:`
* Refactoring with Lexeme as a class now compiles. Basic design seems to work 2014-08-27 19:15:39 +04:00			`string (unicode): The string to be tokenized.`
* Broken version being refactored for docs 2014-08-20 15:39:39 +04:00
			`Returns:`
* Refactoring with Lexeme as a class now compiles. Basic design seems to work 2014-08-27 19:15:39 +04:00			`tokens (Tokens): A Tokens object, giving access to a sequence of LexIDs.`
* Broken version being refactored for docs 2014-08-20 15:39:39 +04:00			`"""`
* Fiddle with token features 2014-09-12 17:49:55 +04:00			`print repr(string)`
* Working version that uses arrays for chunks, which should be more memory efficient 2014-08-18 22:23:54 +04:00			`cdef size_t length = len(string)`
* Switch to returning a Tokens object 2014-09-11 23:37:32 +04:00			`cdef Tokens tokens = self.tokens_class(length)`
* Only store LexemeC structs in the vocabulary, transforming them to Lexeme objects for output. Moving away from Lexeme objects for Tokens soon. 2014-09-11 14:28:38 +04:00			`if length == 0:`
* Switch to returning a Tokens object 2014-09-11 23:37:32 +04:00			`return tokens`
* Only store LexemeC structs in the vocabulary, transforming them to Lexeme objects for output. Moving away from Lexeme objects for Tokens soon. 2014-09-11 14:28:38 +04:00
* Working version, adding improvements 2014-08-18 21:59:59 +04:00			`cdef size_t start = 0`
* Roll back to using unicode, and never Py_UNICODE. No dependence on murmurhash either. 2014-08-18 22:48:48 +04:00			`cdef size_t i = 0`
* Switch to 64 bit hashes, for better reliability 2014-09-12 04:04:47 +04:00			`cdef Py_UNICODE* characters = string`
			`cdef Py_UNICODE c`
			`for i in range(length):`
			`c = characters[i]`
* Improve cache mechanism by including a random element depending on the size of the cache. 2014-09-12 02:18:31 +04:00			`if c == ' ' or c == '\n' or c == '\t':`
* Working version, adding improvements 2014-08-18 21:59:59 +04:00			`if start < i:`
* Switch to 64 bit hashes, for better reliability 2014-09-12 04:04:47 +04:00			`self._tokenize(tokens, &characters[start], i - start)`
* Working version, adding improvements 2014-08-18 21:59:59 +04:00			`start = i + 1`
* Switch to 64 bit hashes, for better reliability 2014-09-12 04:04:47 +04:00			`i += 1`
* Working version, adding improvements 2014-08-18 21:59:59 +04:00			`if start < i:`
* Switch to 64 bit hashes, for better reliability 2014-09-12 04:04:47 +04:00			`self._tokenize(tokens, &characters[start], i - start)`
* Switch to returning a Tokens object 2014-09-11 23:37:32 +04:00			`return tokens`
* Reorganized code to accomodate Tokens class. Need string views before group_by and count_by can be done well. 2014-07-07 14:47:21 +04:00
* Tweak signatures and refactor slightly. Processing gigaword taking 8-9 mins. Tests passing, but some sort of memory bug on exit. 2014-09-12 04:43:36 +04:00			`cdef int _tokenize(self, Tokens tokens, Py_UNICODE* characters, size_t length) except -1:`
* Switch to 64 bit hashes, for better reliability 2014-09-12 04:04:47 +04:00			`cdef uint64_t hashed = hash64(characters, length * sizeof(Py_UNICODE), 0)`
* Changed cache to use a linked-list data structure, to take out Python list code. Taking 6-7 mins for gigaword. 2014-09-12 05:30:50 +04:00			`cdef LexList* node = <LexList*>self.cache[hashed]`
			`if node is not NULL:`
			`while node != NULL:`
			`tokens.push_back(node.lex)`
			`node = node.tail`
* Tweak signatures and refactor slightly. Processing gigaword taking 8-9 mins. Tests passing, but some sort of memory bug on exit. 2014-09-12 04:43:36 +04:00			`return 0`
* Changed cache to use a linked-list data structure, to take out Python list code. Taking 6-7 mins for gigaword. 2014-09-12 05:30:50 +04:00
			`node = <LexList*>calloc(1, sizeof(LexList))`
			`self.cache[hashed] = <size_t>node`
			`cdef size_t start = 0`
			`cdef size_t split = 0`
			`while start < length:`
* Replace main lexicon dict with dense_hash_map. May be unsuitable, if strings need recovery. 2014-09-12 06:29:09 +04:00			`split = self._split_one(&characters[start], length - start)`
			`node.lex = <LexemeC*>self.lexicon.get(&characters[start], split)`
* Changed cache to use a linked-list data structure, to take out Python list code. Taking 6-7 mins for gigaword. 2014-09-12 05:30:50 +04:00			`tokens.push_back(node.lex)`
* Replace main lexicon dict with dense_hash_map. May be unsuitable, if strings need recovery. 2014-09-12 06:29:09 +04:00			`start += split`
			`if start >= length:`
* Changed cache to use a linked-list data structure, to take out Python list code. Taking 6-7 mins for gigaword. 2014-09-12 05:30:50 +04:00			`break`
* Replace main lexicon dict with dense_hash_map. May be unsuitable, if strings need recovery. 2014-09-12 06:29:09 +04:00			`hashed = hash64(&characters[start], (length - start) * sizeof(Py_UNICODE), 0)`
* Changed cache to use a linked-list data structure, to take out Python list code. Taking 6-7 mins for gigaword. 2014-09-12 05:30:50 +04:00			`node.tail = <LexList*>self.cache[hashed]`
			`if node.tail == NULL:`
			`node.tail = <LexList*>calloc(1, sizeof(LexList))`
			`self.cache[hashed] = <size_t>node.tail`
			`node = node.tail`
			`else:`
			`node = node.tail`
			`while node != NULL:`
			`tokens.push_back(node.lex)`
			`node = node.tail`
			`break`
* Refactoring with Lexeme as a class now compiles. Basic design seems to work 2014-08-27 19:15:39 +04:00
* Replace main lexicon dict with dense_hash_map. May be unsuitable, if strings need recovery. 2014-09-12 06:29:09 +04:00			`cdef int _split_one(self, Py_UNICODE* characters, size_t length):`
			`return length`
* Refactoring tokenizer 2014-08-16 05:22:03 +04:00
* Docs coming together 2014-08-29 03:59:23 +04:00			`def _load_special_tokenization(self, token_rules):`
* Broken version being refactored for docs 2014-08-20 15:39:39 +04:00			`'''Load special-case tokenization rules.`

* Refactoring with Lexeme as a class now compiles. Basic design seems to work 2014-08-27 19:15:39 +04:00			`Loads special-case tokenization rules into the Language.cache cache,`
* Broken version being refactored for docs 2014-08-20 15:39:39 +04:00			`read from data/<lang>/tokenization . The special cases are loaded before`
			`any language data is tokenized, giving these priority. For instance,`
			`the English tokenization rules map "ain't" to ["are", "not"].`

			`Args:`
			`token_rules (list): A list of (chunk, tokens) pairs, where chunk is`
			`a string and tokens is a list of strings.`
			`'''`
* Changed cache to use a linked-list data structure, to take out Python list code. Taking 6-7 mins for gigaword. 2014-09-12 05:30:50 +04:00			`cdef LexList* node`
* Switch to 64 bit hashes, for better reliability 2014-09-12 04:04:47 +04:00			`cdef uint64_t hashed`
* Refactoring with Lexeme as a class now compiles. Basic design seems to work 2014-08-27 19:15:39 +04:00			`for string, substrings in token_rules:`
* Switch to 64 bit hashes, for better reliability 2014-09-12 04:04:47 +04:00			`hashed = hash64(<Py_UNICODE>string, len(string) sizeof(Py_UNICODE), 0)`
* Changed cache to use a linked-list data structure, to take out Python list code. Taking 6-7 mins for gigaword. 2014-09-12 05:30:50 +04:00			`node = <LexList*>calloc(1, sizeof(LexList))`
			`self.cache[hashed] = <size_t>node`
			`for substring in substrings[:-1]:`
* Replace main lexicon dict with dense_hash_map. May be unsuitable, if strings need recovery. 2014-09-12 06:29:09 +04:00			`node.lex = <LexemeC>self.lexicon.get(<Py_UNICODE>substring, len(substring))`
* Changed cache to use a linked-list data structure, to take out Python list code. Taking 6-7 mins for gigaword. 2014-09-12 05:30:50 +04:00			`node.tail = <LexList*>calloc(1, sizeof(LexList))`
			`node = node.tail`
* Replace main lexicon dict with dense_hash_map. May be unsuitable, if strings need recovery. 2014-09-12 06:29:09 +04:00			`node.lex = <LexemeC>self.lexicon.get(<Py_UNICODE>substrings[-1], len(substrings[-1]))`
* Refactoring with Lexeme as a class now compiles. Basic design seems to work 2014-08-27 19:15:39 +04:00
* Working version, adding improvements 2014-08-18 21:59:59 +04:00
* Refactoring with Lexeme as a class now compiles. Basic design seems to work 2014-08-27 19:15:39 +04:00			`cdef class Lexicon:`
* Redesign proceeding 2014-08-28 21:45:09 +04:00			`def __cinit__(self, words, probs, clusters, case_stats, tag_stats,`
			`string_features, flag_features):`
* Docs coming together 2014-08-29 03:59:23 +04:00			`self._flag_features = flag_features`
			`self._string_features = string_features`
* Replace main lexicon dict with dense_hash_map. May be unsuitable, if strings need recovery. 2014-09-12 06:29:09 +04:00			`self._dict.set_empty_key(0)`
* Refactoring to use Tokens object 2014-09-10 20:11:13 +04:00			`self.size = 0`
* Redesign proceeding 2014-08-28 21:45:09 +04:00			`cdef Lexeme word`
			`for string in words:`
* Only store LexemeC structs in the vocabulary, transforming them to Lexeme objects for output. Moving away from Lexeme objects for Tokens soon. 2014-09-11 14:28:38 +04:00			`prob = probs.get(string, 0.0)`
			`cluster = clusters.get(string, 0.0)`
			`cases = case_stats.get(string, {})`
			`tags = tag_stats.get(string, {})`
			`views = [string_view(string, prob, cluster, cases, tags)`
			`for string_view in self._string_features]`
			`flags = set()`
			`for i, flag_feature in enumerate(self._flag_features):`
			`if flag_feature(string, prob, cluster, cases, tags):`
			`flags.add(i)`
			`lexeme = lexeme_init(string, prob, cluster, views, flags)`
			`self._dict[string] = <size_t>lexeme`
* Refactoring to use Tokens object 2014-09-10 20:11:13 +04:00			`self.size += 1`
* Broken version being refactored for docs 2014-08-20 15:39:39 +04:00
* Replace main lexicon dict with dense_hash_map. May be unsuitable, if strings need recovery. 2014-09-12 06:29:09 +04:00			`cdef size_t get(self, Py_UNICODE* characters, size_t length):`
			`cdef uint64_t hashed = hash64(characters, length * sizeof(Py_UNICODE), 0)`
			`cdef LexemeC* lexeme = <LexemeC*>self._dict[hashed]`
			`if lexeme != NULL:`
			`return <size_t>lexeme`
* Refactoring with Lexeme as a class now compiles. Basic design seems to work 2014-08-27 19:15:39 +04:00
* Replace main lexicon dict with dense_hash_map. May be unsuitable, if strings need recovery. 2014-09-12 06:29:09 +04:00			`cdef unicode string = characters[:length]`
* Only store LexemeC structs in the vocabulary, transforming them to Lexeme objects for output. Moving away from Lexeme objects for Tokens soon. 2014-09-11 14:28:38 +04:00			`views = [string_view(string, 0.0, 0, {}, {})`
			`for string_view in self._string_features]`
			`flags = set()`
			`for i, flag_feature in enumerate(self._flag_features):`
			`if flag_feature(string, 0.0, {}, {}):`
			`flags.add(i)`

			`lexeme = lexeme_init(string, 0, 0, views, flags)`
* Replace main lexicon dict with dense_hash_map. May be unsuitable, if strings need recovery. 2014-09-12 06:29:09 +04:00			`self._dict[hashed] = <size_t>lexeme`
* Refactoring to use Tokens object 2014-09-10 20:11:13 +04:00			`self.size += 1`
* Moving to storing LexemeC structs internally 2014-09-11 23:54:34 +04:00			`return <size_t>lexeme`

			`cpdef Lexeme lookup(self, unicode string):`
			`"""Retrieve (or create, if not found) a Lexeme for a string, and return it.`

			`Args`
			`string (unicode): The string to be looked up. Must be unicode, not bytes.`

			`Returns:`
			`lexeme (Lexeme): A reference to a lexical type.`
			`"""`
* Replace main lexicon dict with dense_hash_map. May be unsuitable, if strings need recovery. 2014-09-12 06:29:09 +04:00			`cdef size_t lexeme = self.get(<Py_UNICODE*>string, len(string))`
* Moving to storing LexemeC structs internally 2014-09-11 23:54:34 +04:00			`return Lexeme(lexeme)`