2017-05-26 10:45:01 +00:00
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//- 💫 DOCS > USAGE > SPACY 101 > VOCAB & STRINGSTORE
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p
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| Whenever possible, spaCy tries to store data in a vocabulary, the
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| #[+api("vocab") #[code Vocab]], that will be
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| #[strong shared by multiple documents]. To save memory, spaCy also
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2017-05-28 16:19:11 +00:00
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| encodes all strings to #[strong hash values] – in this case for example,
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2017-05-28 23:06:49 +00:00
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| "coffee" has the hash #[code 3197928453018144401]. Entity labels like
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2017-05-28 16:19:11 +00:00
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| "ORG" and part-of-speech tags like "VERB" are also encoded. Internally,
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| spaCy only "speaks" in hash values.
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2017-05-26 10:45:01 +00:00
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+aside
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| #[strong Token]: A word, punctuation mark etc. #[em in context], including
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| its attributes, tags and dependencies.#[br]
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| #[strong Lexeme]: A "word type" with no context. Includes the word shape
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| and flags, e.g. if it's lowercase, a digit or punctuation.#[br]
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| #[strong Doc]: A processed container of tokens in context.#[br]
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| #[strong Vocab]: The collection of lexemes.#[br]
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| #[strong StringStore]: The dictionary mapping hash values to strings, for
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| example #[code 3197928453018144401] → "coffee".
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2017-05-26 10:45:01 +00:00
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+image
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include ../../../assets/img/docs/vocab_stringstore.svg
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.u-text-right
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+button("/assets/img/docs/vocab_stringstore.svg", false, "secondary").u-text-tag View large graphic
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p
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| If you process lots of documents containing the word "coffee" in all
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| kinds of different contexts, storing the exact string "coffee" every time
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| would take up way too much space. So instead, spaCy hashes the string
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| and stores it in the #[+api("stringstore") #[code StringStore]]. You can
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| think of the #[code StringStore] as a
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| #[strong lookup table that works in both directions] – you can look up a
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2017-05-28 16:19:11 +00:00
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| string to get its hash, or a hash to get its string:
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2017-05-26 10:45:01 +00:00
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+code.
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doc = nlp(u'I like coffee')
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assert doc.vocab.strings[u'coffee'] == 3197928453018144401
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assert doc.vocab.strings[3197928453018144401] == u'coffee'
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2017-05-29 09:05:05 +00:00
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+aside("What does 'L' at the end of a hash mean?")
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| If you return a hash value in the #[strong Python 2 interpreter], it'll
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| show up as #[code 3197928453018144401L]. The #[code L] just means "long
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| integer" – it's #[strong not] actually a part of the hash value.
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2017-05-26 10:45:01 +00:00
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p
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| Now that all strings are encoded, the entries in the vocabulary
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| #[strong don't need to include the word text] themselves. Instead,
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2017-05-28 16:19:11 +00:00
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| they can look it up in the #[code StringStore] via its hash value. Each
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2017-05-26 10:45:01 +00:00
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| entry in the vocabulary, also called #[+api("lexeme") #[code Lexeme]],
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| contains the #[strong context-independent] information about a word.
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| For example, no matter if "love" is used as a verb or a noun in some
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| context, its spelling and whether it consists of alphabetic characters
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| won't ever change. Its hash value will also always be the same.
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2017-05-26 10:45:01 +00:00
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+code.
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for word in doc:
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lexeme = doc.vocab[word.text]
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print(lexeme.text, lexeme.orth, lexeme.shape_, lexeme.prefix_, lexeme.suffix_,
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lexeme.is_alpha, lexeme.is_digit, lexeme.is_title, lexeme.lang_)
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+aside
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| #[strong Text]: The original text of the lexeme.#[br]
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| #[strong Orth]: The hash value of the lexeme.#[br]
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| #[strong Shape]: The abstract word shape of the lexeme.#[br]
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| #[strong Prefix]: By default, the first letter of the word string.#[br]
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| #[strong Suffix]: By default, the last three letters of the word string.#[br]
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| #[strong is alpha]: Does the lexeme consist of alphabetic characters?#[br]
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| #[strong is digit]: Does the lexeme consist of digits?#[br]
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2017-05-28 16:19:11 +00:00
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+table(["text", "orth", "shape", "prefix", "suffix", "is_alpha", "is_digit"])
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- var style = [0, 1, 1, 0, 0, 1, 1]
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+annotation-row(["I", "4690420944186131903", "X", "I", "I", true, false], style)
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+annotation-row(["love", "3702023516439754181", "xxxx", "l", "ove", true, false], style)
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+annotation-row(["coffee", "3197928453018144401", "xxxx", "c", "ffe", true, false], style)
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2017-05-26 10:45:01 +00:00
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p
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2017-05-28 16:19:11 +00:00
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| The mapping of words to hashes doesn't depend on any state. To make sure
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| each value is unique, spaCy uses a
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| #[+a("https://en.wikipedia.org/wiki/Hash_function") hash function] to
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| calculate the hash #[strong based on the word string]. This also means
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| that the hash for "coffee" will always be the same, no matter which model
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| you're using or how you've configured spaCy.
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p
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| However, hashes #[strong cannot be reversed] and there's no way to
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2017-05-28 23:06:49 +00:00
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| resolve #[code 3197928453018144401] back to "coffee". All spaCy can do
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2017-05-28 16:19:11 +00:00
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| is look it up in the vocabulary. That's why you always need to make
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| sure all objects you create have access to the same vocabulary. If they
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| don't, spaCy might not be able to find the strings it needs.
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2017-05-26 10:45:01 +00:00
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+code.
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from spacy.tokens import Doc
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from spacy.vocab import Vocab
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doc = nlp(u'I like coffee') # original Doc
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2017-05-28 23:06:49 +00:00
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assert doc.vocab.strings[u'coffee'] == 3197928453018144401 # get hash
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assert doc.vocab.strings[3197928453018144401] == u'coffee' # 👍
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2017-05-28 16:19:11 +00:00
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empty_doc = Doc(Vocab()) # new Doc with empty Vocab
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2017-05-28 23:06:49 +00:00
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# doc.vocab.strings[3197928453018144401] will raise an error :(
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2017-05-28 16:19:11 +00:00
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empty_doc.vocab.strings.add(u'coffee') # add "coffee" and generate hash
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2017-05-28 23:06:49 +00:00
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assert doc.vocab.strings[3197928453018144401] == u'coffee' # 👍
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2017-05-28 16:19:11 +00:00
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new_doc = Doc(doc.vocab) # create new doc with first doc's vocab
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2017-05-28 23:06:49 +00:00
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assert doc.vocab.strings[3197928453018144401] == u'coffee' # 👍
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2017-05-26 10:45:01 +00:00
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p
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2017-05-29 12:14:26 +00:00
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| If the vocabulary doesn't contain a string for #[code 3197928453018144401],
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| spaCy will raise an error. You can re-add "coffee" manually, but this
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| only works if you actually #[em know] that the document contains that
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| word. To prevent this problem, spaCy will also export the #[code Vocab]
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| when you save a #[code Doc] or #[code nlp] object. This will give you
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| the object and its encoded annotations, plus they "key" to decode it.
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