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Data formats | Details on spaCy's input and output data formats |
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This section documents input and output formats of data used by spaCy, including the training config, training data and lexical vocabulary data. For an overview of label schemes used by the models, see the models directory. Each model documents the label schemes used in its components, depending on the data it was trained on.
Training config
Config files define the training process and model pipeline and can be passed to
spacy train
. They use
Thinc's configuration system under the
hood. For details on how to use training configs, see the
usage documentation.
What does the @ mean?
The
@
syntax lets you refer to function names registered in the function registry. For example,@architectures = "spacy.HashEmbedCNN.v1"
refers to a registered function of the name spacy.HashEmbedCNN.v1 and all other values defined in its block will be passed into that function as arguments. Those arguments depend on the registered function. See the usage guide on registered functions for details.
https://github.com/explosion/spaCy/blob/develop/spacy/default_config.cfg
Under the hood, spaCy's configs are powered by our machine learning library
Thinc's config system, which uses
pydantic
for data validation
based on type hints. See
spacy/schemas.py
for the schemas used to validate the default config. Arguments of registered
functions are validated against their type annotations, if available. To debug
your config and check that it's valid, you can run the
spacy debug config
command.
nlp
Example
[nlp] lang = "en" pipeline = ["tagger", "parser", "ner"] load_vocab_data = true before_creation = null after_creation = null after_pipeline_creation = null [nlp.tokenizer] @tokenizers = "spacy.Tokenizer.v1"
Defines the nlp
object, its tokenizer and
processing pipeline component names.
Name | Type | Description | Default |
---|---|---|---|
lang |
str | The language code to use. | null |
pipeline |
List[str] |
Names of pipeline components in order. Should correspond to sections in the [components] block, e.g. [components.ner] . See docs on defining components. |
[] |
load_vocab_data |
bool | Whether to load additional lexeme and vocab data from spacy-lookups-data if available. |
true |
before_creation |
callable | Optional callback to modify Language subclass before it's initialized. |
null |
after_creation |
callable | Optional callback to modify nlp object right after it's initialized. |
null |
after_pipeline_creation |
callable | Optional callback to modify nlp object after the pipeline components have been added. |
null |
tokenizer |
callable | The tokenizer to use. | Tokenizer |
components
Example
[components.textcat] factory = "textcat" labels = ["POSITIVE", "NEGATIVE"] [components.textcat.model] @architectures = "spacy.TextCatBOW.v1" exclusive_classes = false ngram_size = 1 no_output_layer = false
This section includes definitions of the
pipeline components and their models, if
available. Components in this section can be referenced in the pipeline
of the
[nlp]
block. Component blocks need to specify either a factory
(named
function to use to create component) or a source
(name of path of pretrained
model to copy components from). See the docs on
defining pipeline components for details.
paths, system
These sections define variables that can be referenced across the other sections
as variables. For example ${paths:train}
uses the value of train
defined in
the block [paths]
. If your config includes custom registered functions that
need paths, you can define them here. All config values can also be
overwritten on the CLI when you run
spacy train
, which is especially relevant for data paths
that you don't want to hard-code in your config file.
$ python -m spacy train ./config.cfg --paths.train ./corpus/train.spacy
training
This section defines settings and controls for the training and evaluation
process that are used when you run spacy train
.
Name | Type | Description | Default |
---|---|---|---|
seed |
int | The random seed. | ${system:seed} |
dropout |
float | The dropout rate. | 0.1 |
accumulate_gradient |
int | Whether to divide the batch up into substeps. | 1 |
init_tok2vec |
str | Optional path to pretrained tok2vec weights created with spacy pretrain . |
${paths:init_tok2vec} |
raw_text |
str | ${paths:raw} |
|
vectors |
str | null |
|
patience |
int | How many steps to continue without improvement in evaluation score. | 1600 |
max_epochs |
int | Maximum number of epochs to train for. | 0 |
max_steps |
int | Maximum number of update steps to train for. | 20000 |
eval_frequency |
int | How often to evaluate during training (steps). | 200 |
score_weights |
Dict[str, float] |
Score names shown in metrics mapped to their weight towards the final weighted score. See here for details. | {} |
frozen_components |
List[str] |
Pipeline component names that are "frozen" and shouldn't be updated during training. See here for details. | [] |
train_corpus |
callable | Callable that takes the current nlp object and yields Example objects. |
Corpus |
dev_corpus |
callable | Callable that takes the current nlp object and yields Example objects. |
Corpus |
batcher |
callable | Callable that takes an iterator of Doc objects and yields batches of Doc s. |
batch_by_words |
optimizer |
Optimizer |
The optimizer. The learning rate schedule and other settings can be configured as part of the optimizer. | Adam |
pretraining
This section is optional and defines settings and controls for
language model pretraining. It's used when you
run spacy pretrain
.
Name | Type | Description | Default |
---|---|---|---|
max_epochs |
int | Maximum number of epochs. | 1000 |
min_length |
int | Minimum length of examples. | 5 |
max_length |
int | Maximum length of examples. | 500 |
dropout |
float | The dropout rate. | 0.2 |
n_save_every |
int | Saving frequency. | null |
batch_size |
int / Sequence[int] |
The batch size or batch size schedule. | 3000 |
seed |
int | The random seed. | ${system.seed} |
use_pytorch_for_gpu_memory |
bool | Allocate memory via PyTorch. | ${system:use_pytorch_for_gpu_memory} |
tok2vec_model |
str | tok2vec model section in the config. | "components.tok2vec.model" |
objective |
dict | The pretraining objective. | {"type": "characters", "n_characters": 4} |
optimizer |
Optimizer |
The optimizer. | Adam |
Training data
Binary training format
Example
from spacy.tokens import DocBin from spacy.gold import Corpus doc_bin = DocBin(docs=docs) doc_bin.to_disk("./data.spacy") reader = Corpus("./data.spacy")
The main data format used in spaCy v3.0 is a binary format created by
serializing a DocBin
object, which represents a collection of
Doc
objects. This means that you can train spaCy models using the same format
it outputs: annotated Doc
objects. The binary format is extremely efficient
in storage, especially when packing multiple documents together.
Typically, the extension for these binary files is .spacy
, and they are used
as input format for specifying a training corpus and for spaCy's
CLI train
command. The built-in
convert
command helps you convert spaCy's previous
JSON format to the new binary format format. It also supports
conversion of the .conllu
format used by the
Universal Dependencies corpora.
JSON training format
As of v3.0, the JSON input format is deprecated and is replaced by the
binary format. Instead of converting Doc
objects to JSON, you can now serialize them directly using the
DocBin
container and then use them as input data.
spacy convert
lets you convert your JSON data to the new .spacy
format:
$ python -m spacy convert ./data.json ./output
Annotating entities
Named entities are provided in the BILUO notation. Tokens outside an entity are set to
"O"
and tokens that are part of an entity are set to the entity label, prefixed by the BILUO marker. For example"B-ORG"
describes the first token of a multi-tokenORG
entity and"U-PERSON"
a single token representing aPERSON
entity. Thebiluo_tags_from_offsets
function can help you convert entity offsets to the right format.
### Example structure
[{
"id": int, # ID of the document within the corpus
"paragraphs": [{ # list of paragraphs in the corpus
"raw": string, # raw text of the paragraph
"sentences": [{ # list of sentences in the paragraph
"tokens": [{ # list of tokens in the sentence
"id": int, # index of the token in the document
"dep": string, # dependency label
"head": int, # offset of token head relative to token index
"tag": string, # part-of-speech tag
"orth": string, # verbatim text of the token
"ner": string # BILUO label, e.g. "O" or "B-ORG"
}],
"brackets": [{ # phrase structure (NOT USED by current models)
"first": int, # index of first token
"last": int, # index of last token
"label": string # phrase label
}]
}],
"cats": [{ # new in v2.2: categories for text classifier
"label": string, # text category label
"value": float / bool # label applies (1.0/true) or not (0.0/false)
}]
}]
}]
Here's an example of dependencies, part-of-speech tags and names entities, taken from the English Wall Street Journal portion of the Penn Treebank:
https://github.com/explosion/spaCy/blob/v2.3.x/examples/training/training-data.json
Annotation format for creating training examples
An Example
object holds the information for one training
instance. It stores two Doc
objects: one for holding the
gold-standard reference data, and one for holding the predictions of the
pipeline. Examples can be created using the
Example.from_dict
method with a reference Doc
and
a dictionary of gold-standard annotations.
Example
example = Example.from_dict(doc, gold_dict)
Example
objects are used as part of the
internal training API and they're expected when you call
nlp.update
. However, for most use cases, you
shouldn't have to write your own training scripts. It's recommended to train
your models via the spacy train
command with a config file
to keep track of your settings and hyperparameters and your own
registered functions to customize the setup.
Example
{ "text": str, "words": List[str], "lemmas": List[str], "spaces": List[bool], "tags": List[str], "pos": List[str], "morphs": List[str], "sent_starts": List[bool], "deps": List[string], "heads": List[int], "entities": List[str], "entities": List[(int, int, str)], "cats": Dict[str, float], "links": Dict[(int, int), dict], }
Name | Type | Description |
---|---|---|
text |
str | Raw text. |
words |
List[str] |
List of gold-standard tokens. |
lemmas |
List[str] |
List of lemmas. |
spaces |
List[bool] |
List of boolean values indicating whether the corresponding tokens is followed by a space or not. |
tags |
List[str] |
List of fine-grained POS tags. |
pos |
List[str] |
List of coarse-grained POS tags. |
morphs |
List[str] |
List of morphological features. |
sent_starts |
List[bool] |
List of boolean values indicating whether each token is the first of a sentence or not. |
deps |
List[str] |
List of string values indicating the dependency relation of a token to its head. |
heads |
List[int] |
List of integer values indicating the dependency head of each token, referring to the absolute index of each token in the text. |
entities |
List[str] |
Option 1: List of BILUO tags per token of the format "{action}-{label}" , or None for unannotated tokens. |
entities |
List[Tuple[int, int, str]] |
Option 2: List of "(start, end, label)" tuples defining all entities in the text. |
cats |
Dict[str, float] |
Dictionary of label /value pairs indicating how relevant a certain text category is for the text. |
links |
Dict[(int, int), Dict] |
Dictionary of offset /dict pairs defining named entity links. The character offsets are linked to a dictionary of relevant knowledge base IDs. |
- Multiple formats are possible for the "entities" entry, but you have to pick one.
- Any values for sentence starts will be ignored if there are annotations for dependency relations.
- If the dictionary contains values for
"text"
and"words"
, but not"spaces"
, the latter are inferred automatically. If "words" is not provided either, the values are inferred from theDoc
argument.
### Examples
# Training data for a part-of-speech tagger
doc = Doc(vocab, words=["I", "like", "stuff"])
gold_dict = {"tags": ["NOUN", "VERB", "NOUN"]}
example = Example.from_dict(doc, gold_dict)
# Training data for an entity recognizer (option 1)
doc = nlp("Laura flew to Silicon Valley.")
gold_dict = {"entities": ["U-PERS", "O", "O", "B-LOC", "L-LOC"]}
example = Example.from_dict(doc, gold_dict)
# Training data for an entity recognizer (option 2)
doc = nlp("Laura flew to Silicon Valley.")
gold_dict = {"entities": [(0, 5, "PERSON"), (14, 28, "LOC")]}
example = Example.from_dict(doc, gold_dict)
# Training data for text categorization
doc = nlp("I'm pretty happy about that!")
gold_dict = {"cats": {"POSITIVE": 1.0, "NEGATIVE": 0.0}}
example = Example.from_dict(doc, gold_dict)
# Training data for an Entity Linking component
doc = nlp("Russ Cochran his reprints include EC Comics.")
gold_dict = {"links": {(0, 12): {"Q7381115": 1.0, "Q2146908": 0.0}}}
example = Example.from_dict(doc, gold_dict)
Pretraining data
The spacy pretrain
command lets you pretrain the tok2vec
layer of pipeline components from raw text. Raw text can be provided as a
.jsonl
(newline-delimited JSON) file containing one input text per line
(roughly paragraph length is good). Optionally, custom tokenization can be
provided.
Tip: Writing JSONL
Our utility library
srsly
provides a handywrite_jsonl
helper that takes a file path and list of dictionaries and writes out JSONL-formatted data.import srsly data = [{"text": "Some text"}, {"text": "More..."}] srsly.write_jsonl("/path/to/text.jsonl", data)
Key | Type | Description |
---|---|---|
text |
str | The raw input text. Is not required if tokens available. |
tokens |
list | Optional tokenization, one string per token. |
### Example
{"text": "Can I ask where you work now and what you do, and if you enjoy it?"}
{"text": "They may just pull out of the Seattle market completely, at least until they have autonomous vehicles."}
{"text": "My cynical view on this is that it will never be free to the public. Reason: what would be the draw of joining the military? Right now their selling point is free Healthcare and Education. Ironically both are run horribly and most, that I've talked to, come out wishing they never went in."}
{"tokens": ["If", "tokens", "are", "provided", "then", "we", "can", "skip", "the", "raw", "input", "text"]}
Lexical data for vocabulary
To populate a model's vocabulary, you can use the
spacy init-model
command and load in a
newline-delimited JSON (JSONL) file containing one
lexical entry per line via the --jsonl-loc
option. The first line defines the
language and vocabulary settings. All other lines are expected to be JSON
objects describing an individual lexeme. The lexical attributes will be then set
as attributes on spaCy's Lexeme
object. The vocab
command outputs a ready-to-use spaCy model with a Vocab
containing the lexical
data.
### First line
{"lang": "en", "settings": {"oov_prob": -20.502029418945312}}
### Entry structure
{
"orth": string, # the word text
"id": int, # can correspond to row in vectors table
"lower": string,
"norm": string,
"shape": string
"prefix": string,
"suffix": string,
"length": int,
"cluster": string,
"prob": float,
"is_alpha": bool,
"is_ascii": bool,
"is_digit": bool,
"is_lower": bool,
"is_punct": bool,
"is_space": bool,
"is_title": bool,
"is_upper": bool,
"like_url": bool,
"like_num": bool,
"like_email": bool,
"is_stop": bool,
"is_oov": bool,
"is_quote": bool,
"is_left_punct": bool,
"is_right_punct": bool
}
Here's an example of the 20 most frequent lexemes in the English training data:
https://github.com/explosion/spaCy/tree/master/examples/training/vocab-data.jsonl