spaCy/spacy/pipeline/pipes.pyx

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Update draft of parser neural network model Model is good, but code is messy. Currently requires Chainer, which may cause the build to fail on machines without a GPU. Outline of the model: We first predict context-sensitive vectors for each word in the input: (embed_lower | embed_prefix | embed_suffix | embed_shape) >> Maxout(token_width) >> convolution ** 4 This convolutional layer is shared between the tagger and the parser. This prevents the parser from needing tag features. To boost the representation, we make a "super tag" with POS, morphology and dependency label. The tagger predicts this by adding a softmax layer onto the convolutional layer --- so, we're teaching the convolutional layer to give us a representation that's one affine transform from this informative lexical information. This is obviously good for the parser (which backprops to the convolutions too). The parser model makes a state vector by concatenating the vector representations for its context tokens. Current results suggest few context tokens works well. Maybe this is a bug. The current context tokens: * S0, S1, S2: Top three words on the stack * B0, B1: First two words of the buffer * S0L1, S0L2: Leftmost and second leftmost children of S0 * S0R1, S0R2: Rightmost and second rightmost children of S0 * S1L1, S1L2, S1R2, S1R, B0L1, B0L2: Likewise for S1 and B0 This makes the state vector quite long: 13*T, where T is the token vector width (128 is working well). Fortunately, there's a way to structure the computation to save some expense (and make it more GPU friendly). The parser typically visits 2*N states for a sentence of length N (although it may visit more, if it back-tracks with a non-monotonic transition). A naive implementation would require 2*N (B, 13*T) @ (13*T, H) matrix multiplications for a batch of size B. We can instead perform one (B*N, T) @ (T, 13*H) multiplication, to pre-compute the hidden weights for each positional feature wrt the words in the batch. (Note that our token vectors come from the CNN -- so we can't play this trick over the vocabulary. That's how Stanford's NN parser works --- and why its model is so big.) This pre-computation strategy allows a nice compromise between GPU-friendliness and implementation simplicity. The CNN and the wide lower layer are computed on the GPU, and then the precomputed hidden weights are moved to the CPU, before we start the transition-based parsing process. This makes a lot of things much easier. We don't have to worry about variable-length batch sizes, and we don't have to implement the dynamic oracle in CUDA to train. Currently the parser's loss function is multilabel log loss, as the dynamic oracle allows multiple states to be 0 cost. This is defined as: (exp(score) / Z) - (exp(score) / gZ) Where gZ is the sum of the scores assigned to gold classes. I'm very interested in regressing on the cost directly, but so far this isn't working well. Machinery is in place for beam-search, which has been working well for the linear model. Beam search should benefit greatly from the pre-computation trick.
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# cython: infer_types=True
# cython: profile=True
# coding: utf8
from __future__ import unicode_literals
Update draft of parser neural network model Model is good, but code is messy. Currently requires Chainer, which may cause the build to fail on machines without a GPU. Outline of the model: We first predict context-sensitive vectors for each word in the input: (embed_lower | embed_prefix | embed_suffix | embed_shape) >> Maxout(token_width) >> convolution ** 4 This convolutional layer is shared between the tagger and the parser. This prevents the parser from needing tag features. To boost the representation, we make a "super tag" with POS, morphology and dependency label. The tagger predicts this by adding a softmax layer onto the convolutional layer --- so, we're teaching the convolutional layer to give us a representation that's one affine transform from this informative lexical information. This is obviously good for the parser (which backprops to the convolutions too). The parser model makes a state vector by concatenating the vector representations for its context tokens. Current results suggest few context tokens works well. Maybe this is a bug. The current context tokens: * S0, S1, S2: Top three words on the stack * B0, B1: First two words of the buffer * S0L1, S0L2: Leftmost and second leftmost children of S0 * S0R1, S0R2: Rightmost and second rightmost children of S0 * S1L1, S1L2, S1R2, S1R, B0L1, B0L2: Likewise for S1 and B0 This makes the state vector quite long: 13*T, where T is the token vector width (128 is working well). Fortunately, there's a way to structure the computation to save some expense (and make it more GPU friendly). The parser typically visits 2*N states for a sentence of length N (although it may visit more, if it back-tracks with a non-monotonic transition). A naive implementation would require 2*N (B, 13*T) @ (13*T, H) matrix multiplications for a batch of size B. We can instead perform one (B*N, T) @ (T, 13*H) multiplication, to pre-compute the hidden weights for each positional feature wrt the words in the batch. (Note that our token vectors come from the CNN -- so we can't play this trick over the vocabulary. That's how Stanford's NN parser works --- and why its model is so big.) This pre-computation strategy allows a nice compromise between GPU-friendliness and implementation simplicity. The CNN and the wide lower layer are computed on the GPU, and then the precomputed hidden weights are moved to the CPU, before we start the transition-based parsing process. This makes a lot of things much easier. We don't have to worry about variable-length batch sizes, and we don't have to implement the dynamic oracle in CUDA to train. Currently the parser's loss function is multilabel log loss, as the dynamic oracle allows multiple states to be 0 cost. This is defined as: (exp(score) / Z) - (exp(score) / gZ) Where gZ is the sum of the scores assigned to gold classes. I'm very interested in regressing on the cost directly, but so far this isn't working well. Machinery is in place for beam-search, which has been working well for the linear model. Beam search should benefit greatly from the pre-computation trick.
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cimport numpy as np
import numpy
import srsly
from collections import OrderedDict
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from thinc.api import chain
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from thinc.v2v import Affine, Maxout, Softmax
from thinc.misc import LayerNorm
from thinc.neural.util import to_categorical, copy_array
from ..tokens.doc cimport Doc
from ..syntax.nn_parser cimport Parser
from ..syntax.ner cimport BiluoPushDown
from ..syntax.arc_eager cimport ArcEager
from ..morphology cimport Morphology
from ..vocab cimport Vocab
from ..syntax import nonproj
from ..attrs import POS, ID
from ..parts_of_speech import X
from .._ml import Tok2Vec, build_tagger_model
from .._ml import build_text_classifier, build_simple_cnn_text_classifier
from .._ml import link_vectors_to_models, zero_init, flatten
from .._ml import masked_language_model, create_default_optimizer
from ..errors import Errors, TempErrors
from .. import util
def _load_cfg(path):
if path.exists():
return srsly.read_json(path)
else:
return {}
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class Pipe(object):
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"""This class is not instantiated directly. Components inherit from it, and
it defines the interface that components should follow to function as
components in a spaCy analysis pipeline.
"""
name = None
@classmethod
def Model(cls, *shape, **kwargs):
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"""Initialize a model for the pipe."""
raise NotImplementedError
def __init__(self, vocab, model=True, **cfg):
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"""Create a new pipe instance."""
raise NotImplementedError
def __call__(self, doc):
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"""Apply the pipe to one document. The document is
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modified in-place, and returned.
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Both __call__ and pipe should delegate to the `predict()`
and `set_annotations()` methods.
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"""
self.require_model()
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scores, tensors = self.predict([doc])
self.set_annotations([doc], scores, tensors=tensors)
return doc
def require_model(self):
"""Raise an error if the component's model is not initialized."""
if getattr(self, "model", None) in (None, True, False):
raise ValueError(Errors.E109.format(name=self.name))
def pipe(self, stream, batch_size=128, n_threads=-1):
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"""Apply the pipe to a stream of documents.
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Both __call__ and pipe should delegate to the `predict()`
and `set_annotations()` methods.
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"""
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for docs in util.minibatch(stream, size=batch_size):
docs = list(docs)
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scores, tensors = self.predict(docs)
self.set_annotations(docs, scores, tensor=tensors)
yield from docs
def predict(self, docs):
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"""Apply the pipeline's model to a batch of docs, without
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modifying them.
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"""
self.require_model()
raise NotImplementedError
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def set_annotations(self, docs, scores, tensors=None):
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"""Modify a batch of documents, using pre-computed scores."""
raise NotImplementedError
def update(self, docs, golds, drop=0.0, sgd=None, losses=None):
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"""Learn from a batch of documents and gold-standard information,
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updating the pipe's model.
Delegates to predict() and get_loss().
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"""
self.require_model()
raise NotImplementedError
💫 Better support for semi-supervised learning (#3035) The new spacy pretrain command implemented BERT/ULMFit/etc-like transfer learning, using our Language Modelling with Approximate Outputs version of BERT's cloze task. Pretraining is convenient, but in some ways it's a bit of a strange solution. All we're doing is initialising the weights. At the same time, we're putting a lot of work into our optimisation so that it's less sensitive to initial conditions, and more likely to find good optima. I discuss this a bit in the pseudo-rehearsal blog post: https://explosion.ai/blog/pseudo-rehearsal-catastrophic-forgetting Support semi-supervised learning in spacy train One obvious way to improve these pretraining methods is to do multi-task learning, instead of just transfer learning. This has been shown to work very well: https://arxiv.org/pdf/1809.08370.pdf . This patch makes it easy to do this sort of thing. Add a new argument to spacy train, --raw-text. This takes a jsonl file with unlabelled data that can be used in arbitrary ways to do semi-supervised learning. Add a new method to the Language class and to pipeline components, .rehearse(). This is like .update(), but doesn't expect GoldParse objects. It takes a batch of Doc objects, and performs an update on some semi-supervised objective. Move the BERT-LMAO objective out from spacy/cli/pretrain.py into spacy/_ml.py, so we can create a new pipeline component, ClozeMultitask. This can be specified as a parser or NER multitask in the spacy train command. Example usage: python -m spacy train en ./tmp ~/data/en-core-web/train/nw.json ~/data/en-core-web/dev/nw.json --pipeline parser --raw-textt ~/data/unlabelled/reddit-100k.jsonl --vectors en_vectors_web_lg --parser-multitasks cloze Implement rehearsal methods for pipeline components The new --raw-text argument and nlp.rehearse() method also gives us a good place to implement the the idea in the pseudo-rehearsal blog post in the parser. This works as follows: Add a new nlp.resume_training() method. This allocates copies of pre-trained models in the pipeline, setting things up for the rehearsal updates. It also returns an optimizer object. This also greatly reduces confusion around the nlp.begin_training() method, which randomises the weights, making it not suitable for adding new labels or otherwise fine-tuning a pre-trained model. Implement rehearsal updates on the Parser class, making it available for the dependency parser and NER. During rehearsal, the initial model is used to supervise the model being trained. The current model is asked to match the predictions of the initial model on some data. This minimises catastrophic forgetting, by keeping the model's predictions close to the original. See the blog post for details. Implement rehearsal updates for tagger Implement rehearsal updates for text categoriz
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def rehearse(self, docs, sgd=None, losses=None, **config):
pass
def get_loss(self, docs, golds, scores):
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"""Find the loss and gradient of loss for the batch of
documents and their predicted scores."""
raise NotImplementedError
def add_label(self, label):
"""Add an output label, to be predicted by the model.
It's possible to extend pre-trained models with new labels,
but care should be taken to avoid the "catastrophic forgetting"
problem.
"""
raise NotImplementedError
def create_optimizer(self):
return create_default_optimizer(self.model.ops, **self.cfg.get("optimizer", {}))
def begin_training(
self, get_gold_tuples=lambda: [], pipeline=None, sgd=None, **kwargs
):
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"""Initialize the pipe for training, using data exampes if available.
If no model has been initialized yet, the model is added."""
if self.model is True:
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self.model = self.Model(**self.cfg)
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link_vectors_to_models(self.vocab)
if sgd is None:
sgd = self.create_optimizer()
return sgd
def use_params(self, params):
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"""Modify the pipe's model, to use the given parameter values."""
with self.model.use_params(params):
yield
def to_bytes(self, **exclude):
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"""Serialize the pipe to a bytestring."""
serialize = OrderedDict()
serialize["cfg"] = lambda: srsly.json_dumps(self.cfg)
if self.model not in (True, False, None):
serialize["model"] = self.model.to_bytes
serialize["vocab"] = self.vocab.to_bytes
return util.to_bytes(serialize, exclude)
def from_bytes(self, bytes_data, **exclude):
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"""Load the pipe from a bytestring."""
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def load_model(b):
# TODO: Remove this once we don't have to handle previous models
if self.cfg.get("pretrained_dims") and "pretrained_vectors" not in self.cfg:
self.cfg["pretrained_vectors"] = self.vocab.vectors.name
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if self.model is True:
self.model = self.Model(**self.cfg)
self.model.from_bytes(b)
deserialize = OrderedDict(
(
("cfg", lambda b: self.cfg.update(srsly.json_loads(b))),
("vocab", lambda b: self.vocab.from_bytes(b)),
("model", load_model),
)
)
util.from_bytes(bytes_data, deserialize, exclude)
return self
def to_disk(self, path, **exclude):
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"""Serialize the pipe to disk."""
serialize = OrderedDict()
serialize["cfg"] = lambda p: srsly.write_json(p, self.cfg)
serialize["vocab"] = lambda p: self.vocab.to_disk(p)
if self.model not in (None, True, False):
serialize["model"] = lambda p: p.open("wb").write(self.model.to_bytes())
util.to_disk(path, serialize, exclude)
def from_disk(self, path, **exclude):
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"""Load the pipe from disk."""
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def load_model(p):
# TODO: Remove this once we don't have to handle previous models
if self.cfg.get("pretrained_dims") and "pretrained_vectors" not in self.cfg:
self.cfg["pretrained_vectors"] = self.vocab.vectors.name
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if self.model is True:
self.model = self.Model(**self.cfg)
self.model.from_bytes(p.open("rb").read())
deserialize = OrderedDict(
(
("cfg", lambda p: self.cfg.update(_load_cfg(p))),
("vocab", lambda p: self.vocab.from_disk(p)),
("model", load_model),
)
)
util.from_disk(path, deserialize, exclude)
return self
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class Tensorizer(Pipe):
"""Pre-train position-sensitive vectors for tokens."""
name = "tensorizer"
Update draft of parser neural network model Model is good, but code is messy. Currently requires Chainer, which may cause the build to fail on machines without a GPU. Outline of the model: We first predict context-sensitive vectors for each word in the input: (embed_lower | embed_prefix | embed_suffix | embed_shape) >> Maxout(token_width) >> convolution ** 4 This convolutional layer is shared between the tagger and the parser. This prevents the parser from needing tag features. To boost the representation, we make a "super tag" with POS, morphology and dependency label. The tagger predicts this by adding a softmax layer onto the convolutional layer --- so, we're teaching the convolutional layer to give us a representation that's one affine transform from this informative lexical information. This is obviously good for the parser (which backprops to the convolutions too). The parser model makes a state vector by concatenating the vector representations for its context tokens. Current results suggest few context tokens works well. Maybe this is a bug. The current context tokens: * S0, S1, S2: Top three words on the stack * B0, B1: First two words of the buffer * S0L1, S0L2: Leftmost and second leftmost children of S0 * S0R1, S0R2: Rightmost and second rightmost children of S0 * S1L1, S1L2, S1R2, S1R, B0L1, B0L2: Likewise for S1 and B0 This makes the state vector quite long: 13*T, where T is the token vector width (128 is working well). Fortunately, there's a way to structure the computation to save some expense (and make it more GPU friendly). The parser typically visits 2*N states for a sentence of length N (although it may visit more, if it back-tracks with a non-monotonic transition). A naive implementation would require 2*N (B, 13*T) @ (13*T, H) matrix multiplications for a batch of size B. We can instead perform one (B*N, T) @ (T, 13*H) multiplication, to pre-compute the hidden weights for each positional feature wrt the words in the batch. (Note that our token vectors come from the CNN -- so we can't play this trick over the vocabulary. That's how Stanford's NN parser works --- and why its model is so big.) This pre-computation strategy allows a nice compromise between GPU-friendliness and implementation simplicity. The CNN and the wide lower layer are computed on the GPU, and then the precomputed hidden weights are moved to the CPU, before we start the transition-based parsing process. This makes a lot of things much easier. We don't have to worry about variable-length batch sizes, and we don't have to implement the dynamic oracle in CUDA to train. Currently the parser's loss function is multilabel log loss, as the dynamic oracle allows multiple states to be 0 cost. This is defined as: (exp(score) / Z) - (exp(score) / gZ) Where gZ is the sum of the scores assigned to gold classes. I'm very interested in regressing on the cost directly, but so far this isn't working well. Machinery is in place for beam-search, which has been working well for the linear model. Beam search should benefit greatly from the pre-computation trick.
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@classmethod
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def Model(cls, output_size=300, **cfg):
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"""Create a new statistical model for the class.
width (int): Output size of the model.
embed_size (int): Number of vectors in the embedding table.
**cfg: Config parameters.
RETURNS (Model): A `thinc.neural.Model` or similar instance.
"""
input_size = util.env_opt("token_vector_width", cfg.get("input_size", 96))
return zero_init(Affine(output_size, input_size, drop_factor=0.0))
Update draft of parser neural network model Model is good, but code is messy. Currently requires Chainer, which may cause the build to fail on machines without a GPU. Outline of the model: We first predict context-sensitive vectors for each word in the input: (embed_lower | embed_prefix | embed_suffix | embed_shape) >> Maxout(token_width) >> convolution ** 4 This convolutional layer is shared between the tagger and the parser. This prevents the parser from needing tag features. To boost the representation, we make a "super tag" with POS, morphology and dependency label. The tagger predicts this by adding a softmax layer onto the convolutional layer --- so, we're teaching the convolutional layer to give us a representation that's one affine transform from this informative lexical information. This is obviously good for the parser (which backprops to the convolutions too). The parser model makes a state vector by concatenating the vector representations for its context tokens. Current results suggest few context tokens works well. Maybe this is a bug. The current context tokens: * S0, S1, S2: Top three words on the stack * B0, B1: First two words of the buffer * S0L1, S0L2: Leftmost and second leftmost children of S0 * S0R1, S0R2: Rightmost and second rightmost children of S0 * S1L1, S1L2, S1R2, S1R, B0L1, B0L2: Likewise for S1 and B0 This makes the state vector quite long: 13*T, where T is the token vector width (128 is working well). Fortunately, there's a way to structure the computation to save some expense (and make it more GPU friendly). The parser typically visits 2*N states for a sentence of length N (although it may visit more, if it back-tracks with a non-monotonic transition). A naive implementation would require 2*N (B, 13*T) @ (13*T, H) matrix multiplications for a batch of size B. We can instead perform one (B*N, T) @ (T, 13*H) multiplication, to pre-compute the hidden weights for each positional feature wrt the words in the batch. (Note that our token vectors come from the CNN -- so we can't play this trick over the vocabulary. That's how Stanford's NN parser works --- and why its model is so big.) This pre-computation strategy allows a nice compromise between GPU-friendliness and implementation simplicity. The CNN and the wide lower layer are computed on the GPU, and then the precomputed hidden weights are moved to the CPU, before we start the transition-based parsing process. This makes a lot of things much easier. We don't have to worry about variable-length batch sizes, and we don't have to implement the dynamic oracle in CUDA to train. Currently the parser's loss function is multilabel log loss, as the dynamic oracle allows multiple states to be 0 cost. This is defined as: (exp(score) / Z) - (exp(score) / gZ) Where gZ is the sum of the scores assigned to gold classes. I'm very interested in regressing on the cost directly, but so far this isn't working well. Machinery is in place for beam-search, which has been working well for the linear model. Beam search should benefit greatly from the pre-computation trick.
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def __init__(self, vocab, model=True, **cfg):
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"""Construct a new statistical model. Weights are not allocated on
initialisation.
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vocab (Vocab): A `Vocab` instance. The model must share the same
`Vocab` instance with the `Doc` objects it will process.
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model (Model): A `Model` instance or `True` allocate one later.
**cfg: Config parameters.
EXAMPLE:
>>> from spacy.pipeline import TokenVectorEncoder
>>> tok2vec = TokenVectorEncoder(nlp.vocab)
>>> tok2vec.model = tok2vec.Model(128, 5000)
"""
self.vocab = vocab
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self.model = model
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self.input_models = []
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self.cfg = dict(cfg)
self.cfg.setdefault("cnn_maxout_pieces", 3)
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def __call__(self, doc):
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"""Add context-sensitive vectors to a `Doc`, e.g. from a CNN or LSTM
model. Vectors are set to the `Doc.tensor` attribute.
docs (Doc or iterable): One or more documents to add vectors to.
RETURNS (dict or None): Intermediate computations.
"""
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tokvecses = self.predict([doc])
self.set_annotations([doc], tokvecses)
return doc
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def pipe(self, stream, batch_size=128, n_threads=-1):
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"""Process `Doc` objects as a stream.
stream (iterator): A sequence of `Doc` objects to process.
batch_size (int): Number of `Doc` objects to group.
n_threads (int): Number of threads.
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YIELDS (iterator): A sequence of `Doc` objects, in order of input.
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"""
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for docs in util.minibatch(stream, size=batch_size):
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docs = list(docs)
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tensors = self.predict(docs)
self.set_annotations(docs, tensors)
yield from docs
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def predict(self, docs):
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"""Return a single tensor for a batch of documents.
docs (iterable): A sequence of `Doc` objects.
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RETURNS (object): Vector representations for each token in the docs.
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"""
self.require_model()
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inputs = self.model.ops.flatten([doc.tensor for doc in docs])
outputs = self.model(inputs)
return self.model.ops.unflatten(outputs, [len(d) for d in docs])
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def set_annotations(self, docs, tensors):
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"""Set the tensor attribute for a batch of documents.
docs (iterable): A sequence of `Doc` objects.
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tensors (object): Vector representation for each token in the docs.
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"""
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for doc, tensor in zip(docs, tensors):
if tensor.shape[0] != len(doc):
raise ValueError(Errors.E076.format(rows=tensor.shape[0], words=len(doc)))
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doc.tensor = tensor
def update(self, docs, golds, state=None, drop=0.0, sgd=None, losses=None):
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"""Update the model.
docs (iterable): A batch of `Doc` objects.
golds (iterable): A batch of `GoldParse` objects.
drop (float): The droput rate.
sgd (callable): An optimizer.
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RETURNS (dict): Results from the update.
"""
self.require_model()
if isinstance(docs, Doc):
docs = [docs]
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inputs = []
bp_inputs = []
for tok2vec in self.input_models:
tensor, bp_tensor = tok2vec.begin_update(docs, drop=drop)
inputs.append(tensor)
bp_inputs.append(bp_tensor)
inputs = self.model.ops.xp.hstack(inputs)
scores, bp_scores = self.model.begin_update(inputs, drop=drop)
loss, d_scores = self.get_loss(docs, golds, scores)
d_inputs = bp_scores(d_scores, sgd=sgd)
d_inputs = self.model.ops.xp.split(d_inputs, len(self.input_models), axis=1)
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for d_input, bp_input in zip(d_inputs, bp_inputs):
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bp_input(d_input, sgd=sgd)
if losses is not None:
losses.setdefault(self.name, 0.0)
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losses[self.name] += loss
return loss
def get_loss(self, docs, golds, prediction):
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ids = self.model.ops.flatten([doc.to_array(ID).ravel() for doc in docs])
target = self.vocab.vectors.data[ids]
d_scores = (prediction - target) / prediction.shape[0]
loss = (d_scores ** 2).sum()
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return loss, d_scores
def begin_training(self, gold_tuples=lambda: [], pipeline=None, sgd=None, **kwargs):
"""Allocate models, pre-process training data and acquire an
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optimizer.
gold_tuples (iterable): Gold-standard training data.
pipeline (list): The pipeline the model is part of.
"""
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if pipeline is not None:
for name, model in pipeline:
if getattr(model, "tok2vec", None):
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self.input_models.append(model.tok2vec)
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if self.model is True:
self.model = self.Model(**self.cfg)
link_vectors_to_models(self.vocab)
if sgd is None:
sgd = self.create_optimizer()
return sgd
2017-05-18 12:29:51 +03:00
2017-05-29 02:37:57 +03:00
2017-10-26 13:40:40 +03:00
class Tagger(Pipe):
"""Pipeline component for part-of-speech tagging.
DOCS: https://spacy.io/api/tagger
"""
name = "tagger"
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2017-07-23 01:52:47 +03:00
def __init__(self, vocab, model=True, **cfg):
self.vocab = vocab
self.model = model
💫 Better support for semi-supervised learning (#3035) The new spacy pretrain command implemented BERT/ULMFit/etc-like transfer learning, using our Language Modelling with Approximate Outputs version of BERT's cloze task. Pretraining is convenient, but in some ways it's a bit of a strange solution. All we're doing is initialising the weights. At the same time, we're putting a lot of work into our optimisation so that it's less sensitive to initial conditions, and more likely to find good optima. I discuss this a bit in the pseudo-rehearsal blog post: https://explosion.ai/blog/pseudo-rehearsal-catastrophic-forgetting Support semi-supervised learning in spacy train One obvious way to improve these pretraining methods is to do multi-task learning, instead of just transfer learning. This has been shown to work very well: https://arxiv.org/pdf/1809.08370.pdf . This patch makes it easy to do this sort of thing. Add a new argument to spacy train, --raw-text. This takes a jsonl file with unlabelled data that can be used in arbitrary ways to do semi-supervised learning. Add a new method to the Language class and to pipeline components, .rehearse(). This is like .update(), but doesn't expect GoldParse objects. It takes a batch of Doc objects, and performs an update on some semi-supervised objective. Move the BERT-LMAO objective out from spacy/cli/pretrain.py into spacy/_ml.py, so we can create a new pipeline component, ClozeMultitask. This can be specified as a parser or NER multitask in the spacy train command. Example usage: python -m spacy train en ./tmp ~/data/en-core-web/train/nw.json ~/data/en-core-web/dev/nw.json --pipeline parser --raw-textt ~/data/unlabelled/reddit-100k.jsonl --vectors en_vectors_web_lg --parser-multitasks cloze Implement rehearsal methods for pipeline components The new --raw-text argument and nlp.rehearse() method also gives us a good place to implement the the idea in the pseudo-rehearsal blog post in the parser. This works as follows: Add a new nlp.resume_training() method. This allocates copies of pre-trained models in the pipeline, setting things up for the rehearsal updates. It also returns an optimizer object. This also greatly reduces confusion around the nlp.begin_training() method, which randomises the weights, making it not suitable for adding new labels or otherwise fine-tuning a pre-trained model. Implement rehearsal updates on the Parser class, making it available for the dependency parser and NER. During rehearsal, the initial model is used to supervise the model being trained. The current model is asked to match the predictions of the initial model on some data. This minimises catastrophic forgetting, by keeping the model's predictions close to the original. See the blog post for details. Implement rehearsal updates for tagger Implement rehearsal updates for text categoriz
2018-12-10 18:25:33 +03:00
self._rehearsal_model = None
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self.cfg = OrderedDict(sorted(cfg.items()))
self.cfg.setdefault("cnn_maxout_pieces", 2)
@property
def labels(self):
return tuple(self.vocab.morphology.tag_names)
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@property
def tok2vec(self):
if self.model in (None, True, False):
return None
else:
return chain(self.model.tok2vec, flatten)
def __call__(self, doc):
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tags, tokvecs = self.predict([doc])
self.set_annotations([doc], tags, tensors=tokvecs)
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return doc
def pipe(self, stream, batch_size=128, n_threads=-1):
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for docs in util.minibatch(stream, size=batch_size):
docs = list(docs)
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tag_ids, tokvecs = self.predict(docs)
self.set_annotations(docs, tag_ids, tensors=tokvecs)
yield from docs
def predict(self, docs):
self.require_model()
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if not any(len(doc) for doc in docs):
# Handle case where there are no tokens in any docs.
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n_labels = len(self.labels)
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guesses = [self.model.ops.allocate((0, n_labels)) for doc in docs]
tokvecs = self.model.ops.allocate((0, self.model.tok2vec.nO))
return guesses, tokvecs
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tokvecs = self.model.tok2vec(docs)
scores = self.model.softmax(tokvecs)
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guesses = []
for doc_scores in scores:
doc_guesses = doc_scores.argmax(axis=1)
if not isinstance(doc_guesses, numpy.ndarray):
doc_guesses = doc_guesses.get()
guesses.append(doc_guesses)
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return guesses, tokvecs
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def set_annotations(self, docs, batch_tag_ids, tensors=None):
if isinstance(docs, Doc):
docs = [docs]
cdef Doc doc
cdef int idx = 0
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cdef Vocab vocab = self.vocab
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assign_morphology = self.cfg.get("set_morphology", True)
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for i, doc in enumerate(docs):
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doc_tag_ids = batch_tag_ids[i]
if hasattr(doc_tag_ids, "get"):
doc_tag_ids = doc_tag_ids.get()
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for j, tag_id in enumerate(doc_tag_ids):
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# Don't clobber preset POS tags
if doc.c[j].tag == 0:
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if doc.c[j].pos == 0 and assign_morphology:
# Don't clobber preset lemmas
lemma = doc.c[j].lemma
vocab.morphology.assign_tag_id(&doc.c[j], tag_id)
if lemma != 0 and lemma != doc.c[j].lex.orth:
doc.c[j].lemma = lemma
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else:
doc.c[j].tag = self.vocab.strings[self.labels[tag_id]]
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idx += 1
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if tensors is not None and len(tensors):
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if isinstance(doc.tensor, numpy.ndarray) \
and not isinstance(tensors[i], numpy.ndarray):
doc.extend_tensor(tensors[i].get())
else:
doc.extend_tensor(tensors[i])
doc.is_tagged = True
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def update(self, docs, golds, drop=0., sgd=None, losses=None):
self.require_model()
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if losses is not None and self.name not in losses:
losses[self.name] = 0.
tag_scores, bp_tag_scores = self.model.begin_update(docs, drop=drop)
loss, d_tag_scores = self.get_loss(docs, golds, tag_scores)
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bp_tag_scores(d_tag_scores, sgd=sgd)
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if losses is not None:
losses[self.name] += loss
💫 Better support for semi-supervised learning (#3035) The new spacy pretrain command implemented BERT/ULMFit/etc-like transfer learning, using our Language Modelling with Approximate Outputs version of BERT's cloze task. Pretraining is convenient, but in some ways it's a bit of a strange solution. All we're doing is initialising the weights. At the same time, we're putting a lot of work into our optimisation so that it's less sensitive to initial conditions, and more likely to find good optima. I discuss this a bit in the pseudo-rehearsal blog post: https://explosion.ai/blog/pseudo-rehearsal-catastrophic-forgetting Support semi-supervised learning in spacy train One obvious way to improve these pretraining methods is to do multi-task learning, instead of just transfer learning. This has been shown to work very well: https://arxiv.org/pdf/1809.08370.pdf . This patch makes it easy to do this sort of thing. Add a new argument to spacy train, --raw-text. This takes a jsonl file with unlabelled data that can be used in arbitrary ways to do semi-supervised learning. Add a new method to the Language class and to pipeline components, .rehearse(). This is like .update(), but doesn't expect GoldParse objects. It takes a batch of Doc objects, and performs an update on some semi-supervised objective. Move the BERT-LMAO objective out from spacy/cli/pretrain.py into spacy/_ml.py, so we can create a new pipeline component, ClozeMultitask. This can be specified as a parser or NER multitask in the spacy train command. Example usage: python -m spacy train en ./tmp ~/data/en-core-web/train/nw.json ~/data/en-core-web/dev/nw.json --pipeline parser --raw-textt ~/data/unlabelled/reddit-100k.jsonl --vectors en_vectors_web_lg --parser-multitasks cloze Implement rehearsal methods for pipeline components The new --raw-text argument and nlp.rehearse() method also gives us a good place to implement the the idea in the pseudo-rehearsal blog post in the parser. This works as follows: Add a new nlp.resume_training() method. This allocates copies of pre-trained models in the pipeline, setting things up for the rehearsal updates. It also returns an optimizer object. This also greatly reduces confusion around the nlp.begin_training() method, which randomises the weights, making it not suitable for adding new labels or otherwise fine-tuning a pre-trained model. Implement rehearsal updates on the Parser class, making it available for the dependency parser and NER. During rehearsal, the initial model is used to supervise the model being trained. The current model is asked to match the predictions of the initial model on some data. This minimises catastrophic forgetting, by keeping the model's predictions close to the original. See the blog post for details. Implement rehearsal updates for tagger Implement rehearsal updates for text categoriz
2018-12-10 18:25:33 +03:00
def rehearse(self, docs, drop=0., sgd=None, losses=None):
"""Perform a 'rehearsal' update, where we try to match the output of
an initial model.
"""
if self._rehearsal_model is None:
return
guesses, backprop = self.model.begin_update(docs, drop=drop)
target = self._rehearsal_model(docs)
gradient = guesses - target
backprop(gradient, sgd=sgd)
if losses is not None:
losses.setdefault(self.name, 0.0)
losses[self.name] += (gradient**2).sum()
def get_loss(self, docs, golds, scores):
scores = self.model.ops.flatten(scores)
tag_index = {tag: i for i, tag in enumerate(self.labels)}
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cdef int idx = 0
correct = numpy.zeros((scores.shape[0],), dtype="i")
guesses = scores.argmax(axis=1)
known_labels = numpy.ones((scores.shape[0], 1), dtype="f")
Update draft of parser neural network model Model is good, but code is messy. Currently requires Chainer, which may cause the build to fail on machines without a GPU. Outline of the model: We first predict context-sensitive vectors for each word in the input: (embed_lower | embed_prefix | embed_suffix | embed_shape) >> Maxout(token_width) >> convolution ** 4 This convolutional layer is shared between the tagger and the parser. This prevents the parser from needing tag features. To boost the representation, we make a "super tag" with POS, morphology and dependency label. The tagger predicts this by adding a softmax layer onto the convolutional layer --- so, we're teaching the convolutional layer to give us a representation that's one affine transform from this informative lexical information. This is obviously good for the parser (which backprops to the convolutions too). The parser model makes a state vector by concatenating the vector representations for its context tokens. Current results suggest few context tokens works well. Maybe this is a bug. The current context tokens: * S0, S1, S2: Top three words on the stack * B0, B1: First two words of the buffer * S0L1, S0L2: Leftmost and second leftmost children of S0 * S0R1, S0R2: Rightmost and second rightmost children of S0 * S1L1, S1L2, S1R2, S1R, B0L1, B0L2: Likewise for S1 and B0 This makes the state vector quite long: 13*T, where T is the token vector width (128 is working well). Fortunately, there's a way to structure the computation to save some expense (and make it more GPU friendly). The parser typically visits 2*N states for a sentence of length N (although it may visit more, if it back-tracks with a non-monotonic transition). A naive implementation would require 2*N (B, 13*T) @ (13*T, H) matrix multiplications for a batch of size B. We can instead perform one (B*N, T) @ (T, 13*H) multiplication, to pre-compute the hidden weights for each positional feature wrt the words in the batch. (Note that our token vectors come from the CNN -- so we can't play this trick over the vocabulary. That's how Stanford's NN parser works --- and why its model is so big.) This pre-computation strategy allows a nice compromise between GPU-friendliness and implementation simplicity. The CNN and the wide lower layer are computed on the GPU, and then the precomputed hidden weights are moved to the CPU, before we start the transition-based parsing process. This makes a lot of things much easier. We don't have to worry about variable-length batch sizes, and we don't have to implement the dynamic oracle in CUDA to train. Currently the parser's loss function is multilabel log loss, as the dynamic oracle allows multiple states to be 0 cost. This is defined as: (exp(score) / Z) - (exp(score) / gZ) Where gZ is the sum of the scores assigned to gold classes. I'm very interested in regressing on the cost directly, but so far this isn't working well. Machinery is in place for beam-search, which has been working well for the linear model. Beam search should benefit greatly from the pre-computation trick.
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for gold in golds:
for tag in gold.tags:
if tag is None:
correct[idx] = guesses[idx]
elif tag in tag_index:
correct[idx] = tag_index[tag]
else:
correct[idx] = 0
known_labels[idx] = 0.
Update draft of parser neural network model Model is good, but code is messy. Currently requires Chainer, which may cause the build to fail on machines without a GPU. Outline of the model: We first predict context-sensitive vectors for each word in the input: (embed_lower | embed_prefix | embed_suffix | embed_shape) >> Maxout(token_width) >> convolution ** 4 This convolutional layer is shared between the tagger and the parser. This prevents the parser from needing tag features. To boost the representation, we make a "super tag" with POS, morphology and dependency label. The tagger predicts this by adding a softmax layer onto the convolutional layer --- so, we're teaching the convolutional layer to give us a representation that's one affine transform from this informative lexical information. This is obviously good for the parser (which backprops to the convolutions too). The parser model makes a state vector by concatenating the vector representations for its context tokens. Current results suggest few context tokens works well. Maybe this is a bug. The current context tokens: * S0, S1, S2: Top three words on the stack * B0, B1: First two words of the buffer * S0L1, S0L2: Leftmost and second leftmost children of S0 * S0R1, S0R2: Rightmost and second rightmost children of S0 * S1L1, S1L2, S1R2, S1R, B0L1, B0L2: Likewise for S1 and B0 This makes the state vector quite long: 13*T, where T is the token vector width (128 is working well). Fortunately, there's a way to structure the computation to save some expense (and make it more GPU friendly). The parser typically visits 2*N states for a sentence of length N (although it may visit more, if it back-tracks with a non-monotonic transition). A naive implementation would require 2*N (B, 13*T) @ (13*T, H) matrix multiplications for a batch of size B. We can instead perform one (B*N, T) @ (T, 13*H) multiplication, to pre-compute the hidden weights for each positional feature wrt the words in the batch. (Note that our token vectors come from the CNN -- so we can't play this trick over the vocabulary. That's how Stanford's NN parser works --- and why its model is so big.) This pre-computation strategy allows a nice compromise between GPU-friendliness and implementation simplicity. The CNN and the wide lower layer are computed on the GPU, and then the precomputed hidden weights are moved to the CPU, before we start the transition-based parsing process. This makes a lot of things much easier. We don't have to worry about variable-length batch sizes, and we don't have to implement the dynamic oracle in CUDA to train. Currently the parser's loss function is multilabel log loss, as the dynamic oracle allows multiple states to be 0 cost. This is defined as: (exp(score) / Z) - (exp(score) / gZ) Where gZ is the sum of the scores assigned to gold classes. I'm very interested in regressing on the cost directly, but so far this isn't working well. Machinery is in place for beam-search, which has been working well for the linear model. Beam search should benefit greatly from the pre-computation trick.
2017-05-13 00:09:15 +03:00
idx += 1
correct = self.model.ops.xp.array(correct, dtype="i")
Update draft of parser neural network model Model is good, but code is messy. Currently requires Chainer, which may cause the build to fail on machines without a GPU. Outline of the model: We first predict context-sensitive vectors for each word in the input: (embed_lower | embed_prefix | embed_suffix | embed_shape) >> Maxout(token_width) >> convolution ** 4 This convolutional layer is shared between the tagger and the parser. This prevents the parser from needing tag features. To boost the representation, we make a "super tag" with POS, morphology and dependency label. The tagger predicts this by adding a softmax layer onto the convolutional layer --- so, we're teaching the convolutional layer to give us a representation that's one affine transform from this informative lexical information. This is obviously good for the parser (which backprops to the convolutions too). The parser model makes a state vector by concatenating the vector representations for its context tokens. Current results suggest few context tokens works well. Maybe this is a bug. The current context tokens: * S0, S1, S2: Top three words on the stack * B0, B1: First two words of the buffer * S0L1, S0L2: Leftmost and second leftmost children of S0 * S0R1, S0R2: Rightmost and second rightmost children of S0 * S1L1, S1L2, S1R2, S1R, B0L1, B0L2: Likewise for S1 and B0 This makes the state vector quite long: 13*T, where T is the token vector width (128 is working well). Fortunately, there's a way to structure the computation to save some expense (and make it more GPU friendly). The parser typically visits 2*N states for a sentence of length N (although it may visit more, if it back-tracks with a non-monotonic transition). A naive implementation would require 2*N (B, 13*T) @ (13*T, H) matrix multiplications for a batch of size B. We can instead perform one (B*N, T) @ (T, 13*H) multiplication, to pre-compute the hidden weights for each positional feature wrt the words in the batch. (Note that our token vectors come from the CNN -- so we can't play this trick over the vocabulary. That's how Stanford's NN parser works --- and why its model is so big.) This pre-computation strategy allows a nice compromise between GPU-friendliness and implementation simplicity. The CNN and the wide lower layer are computed on the GPU, and then the precomputed hidden weights are moved to the CPU, before we start the transition-based parsing process. This makes a lot of things much easier. We don't have to worry about variable-length batch sizes, and we don't have to implement the dynamic oracle in CUDA to train. Currently the parser's loss function is multilabel log loss, as the dynamic oracle allows multiple states to be 0 cost. This is defined as: (exp(score) / Z) - (exp(score) / gZ) Where gZ is the sum of the scores assigned to gold classes. I'm very interested in regressing on the cost directly, but so far this isn't working well. Machinery is in place for beam-search, which has been working well for the linear model. Beam search should benefit greatly from the pre-computation trick.
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d_scores = scores - to_categorical(correct, nb_classes=scores.shape[1])
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d_scores *= self.model.ops.asarray(known_labels)
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loss = (d_scores**2).sum()
d_scores = self.model.ops.unflatten(d_scores, [len(d) for d in docs])
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return float(loss), d_scores
def begin_training(self, get_gold_tuples=lambda: [], pipeline=None, sgd=None,
**kwargs):
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orig_tag_map = dict(self.vocab.morphology.tag_map)
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new_tag_map = OrderedDict()
for raw_text, annots_brackets in get_gold_tuples():
for annots, brackets in annots_brackets:
ids, words, tags, heads, deps, ents = annots
for tag in tags:
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if tag in orig_tag_map:
new_tag_map[tag] = orig_tag_map[tag]
else:
new_tag_map[tag] = {POS: X}
cdef Vocab vocab = self.vocab
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if new_tag_map:
vocab.morphology = Morphology(vocab.strings, new_tag_map,
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vocab.morphology.lemmatizer,
exc=vocab.morphology.exc)
self.cfg["pretrained_vectors"] = kwargs.get("pretrained_vectors")
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if self.model is True:
for hp in ["token_vector_width", "conv_depth"]:
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if hp in kwargs:
self.cfg[hp] = kwargs[hp]
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self.model = self.Model(self.vocab.morphology.n_tags, **self.cfg)
link_vectors_to_models(self.vocab)
if sgd is None:
sgd = self.create_optimizer()
return sgd
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@classmethod
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def Model(cls, n_tags, **cfg):
if cfg.get("pretrained_dims") and not cfg.get("pretrained_vectors"):
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raise ValueError(TempErrors.T008)
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return build_tagger_model(n_tags, **cfg)
def add_label(self, label, values=None):
if label in self.labels:
return 0
if self.model not in (True, False, None):
# Here's how the model resizing will work, once the
# neuron-to-tag mapping is no longer controlled by
# the Morphology class, which sorts the tag names.
# The sorting makes adding labels difficult.
# smaller = self.model._layers[-1]
# larger = Softmax(len(self.labels)+1, smaller.nI)
# copy_array(larger.W[:smaller.nO], smaller.W)
# copy_array(larger.b[:smaller.nO], smaller.b)
# self.model._layers[-1] = larger
raise ValueError(TempErrors.T003)
tag_map = dict(self.vocab.morphology.tag_map)
if values is None:
values = {POS: "X"}
tag_map[label] = values
self.vocab.morphology = Morphology(
self.vocab.strings, tag_map=tag_map,
lemmatizer=self.vocab.morphology.lemmatizer,
exc=self.vocab.morphology.exc)
return 1
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def use_params(self, params):
with self.model.use_params(params):
yield
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def to_bytes(self, **exclude):
serialize = OrderedDict()
if self.model not in (None, True, False):
serialize["model"] = self.model.to_bytes
serialize["vocab"] = self.vocab.to_bytes
serialize["cfg"] = lambda: srsly.json_dumps(self.cfg)
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tag_map = OrderedDict(sorted(self.vocab.morphology.tag_map.items()))
serialize["tag_map"] = lambda: srsly.msgpack_dumps(tag_map)
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return util.to_bytes(serialize, exclude)
def from_bytes(self, bytes_data, **exclude):
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def load_model(b):
# TODO: Remove this once we don't have to handle previous models
if self.cfg.get("pretrained_dims") and "pretrained_vectors" not in self.cfg:
self.cfg["pretrained_vectors"] = self.vocab.vectors.name
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if self.model is True:
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token_vector_width = util.env_opt(
"token_vector_width",
self.cfg.get("token_vector_width", 96))
self.model = self.Model(self.vocab.morphology.n_tags, **self.cfg)
self.model.from_bytes(b)
def load_tag_map(b):
tag_map = srsly.msgpack_loads(b)
self.vocab.morphology = Morphology(
self.vocab.strings, tag_map=tag_map,
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lemmatizer=self.vocab.morphology.lemmatizer,
exc=self.vocab.morphology.exc)
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deserialize = OrderedDict((
("vocab", lambda b: self.vocab.from_bytes(b)),
("tag_map", load_tag_map),
("cfg", lambda b: self.cfg.update(srsly.json_loads(b))),
("model", lambda b: load_model(b)),
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))
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util.from_bytes(bytes_data, deserialize, exclude)
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return self
def to_disk(self, path, **exclude):
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tag_map = OrderedDict(sorted(self.vocab.morphology.tag_map.items()))
serialize = OrderedDict((
('vocab', lambda p: self.vocab.to_disk(p)),
('tag_map', lambda p: srsly.write_msgpack(p, tag_map)),
('model', lambda p: p.open("wb").write(self.model.to_bytes())),
('cfg', lambda p: srsly.write_json(p, self.cfg))
))
util.to_disk(path, serialize, exclude)
def from_disk(self, path, **exclude):
def load_model(p):
# TODO: Remove this once we don't have to handle previous models
if self.cfg.get("pretrained_dims") and "pretrained_vectors" not in self.cfg:
self.cfg["pretrained_vectors"] = self.vocab.vectors.name
if self.model is True:
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self.model = self.Model(self.vocab.morphology.n_tags, **self.cfg)
with p.open("rb") as file_:
self.model.from_bytes(file_.read())
def load_tag_map(p):
tag_map = srsly.read_msgpack(p)
self.vocab.morphology = Morphology(
self.vocab.strings, tag_map=tag_map,
2017-06-05 00:34:32 +03:00
lemmatizer=self.vocab.morphology.lemmatizer,
exc=self.vocab.morphology.exc)
deserialize = OrderedDict((
("cfg", lambda p: self.cfg.update(_load_cfg(p))),
("vocab", lambda p: self.vocab.from_disk(p)),
("tag_map", load_tag_map),
("model", load_model),
))
util.from_disk(path, deserialize, exclude)
return self
2017-05-29 11:14:20 +03:00
class MultitaskObjective(Tagger):
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"""Experimental: Assist training of a parser or tagger, by training a
side-objective.
"""
name = "nn_labeller"
2017-10-27 21:29:08 +03:00
def __init__(self, vocab, model=True, target='dep_tag_offset', **cfg):
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self.vocab = vocab
self.model = model
if target == "dep":
self.make_label = self.make_dep
elif target == "tag":
self.make_label = self.make_tag
elif target == "ent":
self.make_label = self.make_ent
elif target == "dep_tag_offset":
self.make_label = self.make_dep_tag_offset
elif target == "ent_tag":
self.make_label = self.make_ent_tag
elif target == "sent_start":
self.make_label = self.make_sent_start
elif hasattr(target, "__call__"):
self.make_label = target
else:
raise ValueError(Errors.E016)
2017-07-23 01:52:47 +03:00
self.cfg = dict(cfg)
self.cfg.setdefault("cnn_maxout_pieces", 2)
2017-07-23 01:52:47 +03:00
@property
def labels(self):
return self.cfg.setdefault("labels", {})
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@labels.setter
def labels(self, value):
self.cfg["labels"] = value
2017-05-22 01:52:30 +03:00
2017-11-03 13:20:05 +03:00
def set_annotations(self, docs, dep_ids, tensors=None):
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pass
def begin_training(self, get_gold_tuples=lambda: [], pipeline=None, tok2vec=None,
sgd=None, **kwargs):
gold_tuples = nonproj.preprocess_training_data(get_gold_tuples())
2017-05-22 01:52:30 +03:00
for raw_text, annots_brackets in gold_tuples:
for annots, brackets in annots_brackets:
ids, words, tags, heads, deps, ents = annots
for i in range(len(ids)):
label = self.make_label(i, words, tags, heads, deps, ents)
if label is not None and label not in self.labels:
self.labels[label] = len(self.labels)
2017-05-29 21:23:47 +03:00
if self.model is True:
token_vector_width = util.env_opt("token_vector_width")
2018-01-21 21:21:34 +03:00
self.model = self.Model(len(self.labels), tok2vec=tok2vec)
link_vectors_to_models(self.vocab)
if sgd is None:
sgd = self.create_optimizer()
return sgd
2017-05-29 21:23:47 +03:00
@classmethod
def Model(cls, n_tags, tok2vec=None, **cfg):
token_vector_width = util.env_opt("token_vector_width", 96)
2018-12-01 16:41:24 +03:00
softmax = Softmax(n_tags, token_vector_width*2)
2018-01-21 21:21:34 +03:00
model = chain(
tok2vec,
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LayerNorm(Maxout(token_vector_width*2, token_vector_width, pieces=3)),
2018-01-21 21:21:34 +03:00
softmax
)
model.tok2vec = tok2vec
model.softmax = softmax
return model
def predict(self, docs):
self.require_model()
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tokvecs = self.model.tok2vec(docs)
scores = self.model.softmax(tokvecs)
return tokvecs, scores
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def get_loss(self, docs, golds, scores):
if len(docs) != len(golds):
raise ValueError(Errors.E077.format(value="loss", n_docs=len(docs),
n_golds=len(golds)))
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cdef int idx = 0
correct = numpy.zeros((scores.shape[0],), dtype="i")
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guesses = scores.argmax(axis=1)
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for i, gold in enumerate(golds):
for j in range(len(docs[i])):
# Handes alignment for tokenization differences
label = self.make_label(j, gold.words, gold.tags,
2018-02-17 20:41:18 +03:00
gold.heads, gold.labels, gold.ents)
if label is None or label not in self.labels:
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correct[idx] = guesses[idx]
else:
correct[idx] = self.labels[label]
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idx += 1
correct = self.model.ops.xp.array(correct, dtype="i")
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d_scores = scores - to_categorical(correct, nb_classes=scores.shape[1])
loss = (d_scores**2).sum()
return float(loss), d_scores
@staticmethod
def make_dep(i, words, tags, heads, deps, ents):
if deps[i] is None or heads[i] is None:
return None
return deps[i]
@staticmethod
def make_tag(i, words, tags, heads, deps, ents):
return tags[i]
@staticmethod
def make_ent(i, words, tags, heads, deps, ents):
if ents is None:
return None
return ents[i]
@staticmethod
def make_dep_tag_offset(i, words, tags, heads, deps, ents):
if deps[i] is None or heads[i] is None:
return None
offset = heads[i] - i
offset = min(offset, 2)
offset = max(offset, -2)
return "%s-%s:%d" % (deps[i], tags[i], offset)
@staticmethod
def make_ent_tag(i, words, tags, heads, deps, ents):
if ents is None or ents[i] is None:
return None
else:
return "%s-%s" % (tags[i], ents[i])
@staticmethod
def make_sent_start(target, words, tags, heads, deps, ents, cache=True, _cache={}):
"""A multi-task objective for representing sentence boundaries,
using BILU scheme. (O is impossible)
The implementation of this method uses an internal cache that relies
on the identity of the heads array, to avoid requiring a new piece
of gold data. You can pass cache=False if you know the cache will
do the wrong thing.
"""
assert len(words) == len(heads)
assert target < len(words), (target, len(words))
if cache:
if id(heads) in _cache:
return _cache[id(heads)][target]
else:
for key in list(_cache.keys()):
_cache.pop(key)
sent_tags = ["I-SENT"] * len(words)
_cache[id(heads)] = sent_tags
else:
sent_tags = ["I-SENT"] * len(words)
def _find_root(child):
seen = set([child])
while child is not None and heads[child] != child:
seen.add(child)
child = heads[child]
return child
sentences = {}
for i in range(len(words)):
root = _find_root(i)
if root is None:
sent_tags[i] = None
else:
sentences.setdefault(root, []).append(i)
for root, span in sorted(sentences.items()):
if len(span) == 1:
sent_tags[span[0]] = "U-SENT"
else:
sent_tags[span[0]] = "B-SENT"
sent_tags[span[-1]] = "L-SENT"
return sent_tags[target]
💫 Better support for semi-supervised learning (#3035) The new spacy pretrain command implemented BERT/ULMFit/etc-like transfer learning, using our Language Modelling with Approximate Outputs version of BERT's cloze task. Pretraining is convenient, but in some ways it's a bit of a strange solution. All we're doing is initialising the weights. At the same time, we're putting a lot of work into our optimisation so that it's less sensitive to initial conditions, and more likely to find good optima. I discuss this a bit in the pseudo-rehearsal blog post: https://explosion.ai/blog/pseudo-rehearsal-catastrophic-forgetting Support semi-supervised learning in spacy train One obvious way to improve these pretraining methods is to do multi-task learning, instead of just transfer learning. This has been shown to work very well: https://arxiv.org/pdf/1809.08370.pdf . This patch makes it easy to do this sort of thing. Add a new argument to spacy train, --raw-text. This takes a jsonl file with unlabelled data that can be used in arbitrary ways to do semi-supervised learning. Add a new method to the Language class and to pipeline components, .rehearse(). This is like .update(), but doesn't expect GoldParse objects. It takes a batch of Doc objects, and performs an update on some semi-supervised objective. Move the BERT-LMAO objective out from spacy/cli/pretrain.py into spacy/_ml.py, so we can create a new pipeline component, ClozeMultitask. This can be specified as a parser or NER multitask in the spacy train command. Example usage: python -m spacy train en ./tmp ~/data/en-core-web/train/nw.json ~/data/en-core-web/dev/nw.json --pipeline parser --raw-textt ~/data/unlabelled/reddit-100k.jsonl --vectors en_vectors_web_lg --parser-multitasks cloze Implement rehearsal methods for pipeline components The new --raw-text argument and nlp.rehearse() method also gives us a good place to implement the the idea in the pseudo-rehearsal blog post in the parser. This works as follows: Add a new nlp.resume_training() method. This allocates copies of pre-trained models in the pipeline, setting things up for the rehearsal updates. It also returns an optimizer object. This also greatly reduces confusion around the nlp.begin_training() method, which randomises the weights, making it not suitable for adding new labels or otherwise fine-tuning a pre-trained model. Implement rehearsal updates on the Parser class, making it available for the dependency parser and NER. During rehearsal, the initial model is used to supervise the model being trained. The current model is asked to match the predictions of the initial model on some data. This minimises catastrophic forgetting, by keeping the model's predictions close to the original. See the blog post for details. Implement rehearsal updates for tagger Implement rehearsal updates for text categoriz
2018-12-10 18:25:33 +03:00
class ClozeMultitask(Pipe):
@classmethod
def Model(cls, vocab, tok2vec, **cfg):
output_size = vocab.vectors.data.shape[1]
output_layer = chain(
LayerNorm(Maxout(output_size, tok2vec.nO, pieces=3)),
zero_init(Affine(output_size, output_size, drop_factor=0.0))
)
model = chain(tok2vec, output_layer)
model = masked_language_model(vocab, model)
model.tok2vec = tok2vec
model.output_layer = output_layer
return model
def __init__(self, vocab, model=True, **cfg):
self.vocab = vocab
self.model = model
self.cfg = cfg
def set_annotations(self, docs, dep_ids, tensors=None):
pass
def begin_training(self, get_gold_tuples=lambda: [], pipeline=None,
tok2vec=None, sgd=None, **kwargs):
link_vectors_to_models(self.vocab)
if self.model is True:
self.model = self.Model(self.vocab, tok2vec)
X = self.model.ops.allocate((5, self.model.tok2vec.nO))
self.model.output_layer.begin_training(X)
if sgd is None:
sgd = self.create_optimizer()
return sgd
def predict(self, docs):
self.require_model()
💫 Better support for semi-supervised learning (#3035) The new spacy pretrain command implemented BERT/ULMFit/etc-like transfer learning, using our Language Modelling with Approximate Outputs version of BERT's cloze task. Pretraining is convenient, but in some ways it's a bit of a strange solution. All we're doing is initialising the weights. At the same time, we're putting a lot of work into our optimisation so that it's less sensitive to initial conditions, and more likely to find good optima. I discuss this a bit in the pseudo-rehearsal blog post: https://explosion.ai/blog/pseudo-rehearsal-catastrophic-forgetting Support semi-supervised learning in spacy train One obvious way to improve these pretraining methods is to do multi-task learning, instead of just transfer learning. This has been shown to work very well: https://arxiv.org/pdf/1809.08370.pdf . This patch makes it easy to do this sort of thing. Add a new argument to spacy train, --raw-text. This takes a jsonl file with unlabelled data that can be used in arbitrary ways to do semi-supervised learning. Add a new method to the Language class and to pipeline components, .rehearse(). This is like .update(), but doesn't expect GoldParse objects. It takes a batch of Doc objects, and performs an update on some semi-supervised objective. Move the BERT-LMAO objective out from spacy/cli/pretrain.py into spacy/_ml.py, so we can create a new pipeline component, ClozeMultitask. This can be specified as a parser or NER multitask in the spacy train command. Example usage: python -m spacy train en ./tmp ~/data/en-core-web/train/nw.json ~/data/en-core-web/dev/nw.json --pipeline parser --raw-textt ~/data/unlabelled/reddit-100k.jsonl --vectors en_vectors_web_lg --parser-multitasks cloze Implement rehearsal methods for pipeline components The new --raw-text argument and nlp.rehearse() method also gives us a good place to implement the the idea in the pseudo-rehearsal blog post in the parser. This works as follows: Add a new nlp.resume_training() method. This allocates copies of pre-trained models in the pipeline, setting things up for the rehearsal updates. It also returns an optimizer object. This also greatly reduces confusion around the nlp.begin_training() method, which randomises the weights, making it not suitable for adding new labels or otherwise fine-tuning a pre-trained model. Implement rehearsal updates on the Parser class, making it available for the dependency parser and NER. During rehearsal, the initial model is used to supervise the model being trained. The current model is asked to match the predictions of the initial model on some data. This minimises catastrophic forgetting, by keeping the model's predictions close to the original. See the blog post for details. Implement rehearsal updates for tagger Implement rehearsal updates for text categoriz
2018-12-10 18:25:33 +03:00
tokvecs = self.model.tok2vec(docs)
vectors = self.model.output_layer(tokvecs)
return tokvecs, vectors
def get_loss(self, docs, vectors, prediction):
# The simplest way to implement this would be to vstack the
# token.vector values, but that's a bit inefficient, especially on GPU.
# Instead we fetch the index into the vectors table for each of our tokens,
# and look them up all at once. This prevents data copying.
ids = self.model.ops.flatten([doc.to_array(ID).ravel() for doc in docs])
target = vectors[ids]
gradient = (prediction - target) / prediction.shape[0]
loss = (gradient**2).sum()
return float(loss), gradient
2019-02-05 14:32:20 +03:00
💫 Better support for semi-supervised learning (#3035) The new spacy pretrain command implemented BERT/ULMFit/etc-like transfer learning, using our Language Modelling with Approximate Outputs version of BERT's cloze task. Pretraining is convenient, but in some ways it's a bit of a strange solution. All we're doing is initialising the weights. At the same time, we're putting a lot of work into our optimisation so that it's less sensitive to initial conditions, and more likely to find good optima. I discuss this a bit in the pseudo-rehearsal blog post: https://explosion.ai/blog/pseudo-rehearsal-catastrophic-forgetting Support semi-supervised learning in spacy train One obvious way to improve these pretraining methods is to do multi-task learning, instead of just transfer learning. This has been shown to work very well: https://arxiv.org/pdf/1809.08370.pdf . This patch makes it easy to do this sort of thing. Add a new argument to spacy train, --raw-text. This takes a jsonl file with unlabelled data that can be used in arbitrary ways to do semi-supervised learning. Add a new method to the Language class and to pipeline components, .rehearse(). This is like .update(), but doesn't expect GoldParse objects. It takes a batch of Doc objects, and performs an update on some semi-supervised objective. Move the BERT-LMAO objective out from spacy/cli/pretrain.py into spacy/_ml.py, so we can create a new pipeline component, ClozeMultitask. This can be specified as a parser or NER multitask in the spacy train command. Example usage: python -m spacy train en ./tmp ~/data/en-core-web/train/nw.json ~/data/en-core-web/dev/nw.json --pipeline parser --raw-textt ~/data/unlabelled/reddit-100k.jsonl --vectors en_vectors_web_lg --parser-multitasks cloze Implement rehearsal methods for pipeline components The new --raw-text argument and nlp.rehearse() method also gives us a good place to implement the the idea in the pseudo-rehearsal blog post in the parser. This works as follows: Add a new nlp.resume_training() method. This allocates copies of pre-trained models in the pipeline, setting things up for the rehearsal updates. It also returns an optimizer object. This also greatly reduces confusion around the nlp.begin_training() method, which randomises the weights, making it not suitable for adding new labels or otherwise fine-tuning a pre-trained model. Implement rehearsal updates on the Parser class, making it available for the dependency parser and NER. During rehearsal, the initial model is used to supervise the model being trained. The current model is asked to match the predictions of the initial model on some data. This minimises catastrophic forgetting, by keeping the model's predictions close to the original. See the blog post for details. Implement rehearsal updates for tagger Implement rehearsal updates for text categoriz
2018-12-10 18:25:33 +03:00
def update(self, docs, golds, drop=0., sgd=None, losses=None):
pass
def rehearse(self, docs, drop=0., sgd=None, losses=None):
self.require_model()
💫 Better support for semi-supervised learning (#3035) The new spacy pretrain command implemented BERT/ULMFit/etc-like transfer learning, using our Language Modelling with Approximate Outputs version of BERT's cloze task. Pretraining is convenient, but in some ways it's a bit of a strange solution. All we're doing is initialising the weights. At the same time, we're putting a lot of work into our optimisation so that it's less sensitive to initial conditions, and more likely to find good optima. I discuss this a bit in the pseudo-rehearsal blog post: https://explosion.ai/blog/pseudo-rehearsal-catastrophic-forgetting Support semi-supervised learning in spacy train One obvious way to improve these pretraining methods is to do multi-task learning, instead of just transfer learning. This has been shown to work very well: https://arxiv.org/pdf/1809.08370.pdf . This patch makes it easy to do this sort of thing. Add a new argument to spacy train, --raw-text. This takes a jsonl file with unlabelled data that can be used in arbitrary ways to do semi-supervised learning. Add a new method to the Language class and to pipeline components, .rehearse(). This is like .update(), but doesn't expect GoldParse objects. It takes a batch of Doc objects, and performs an update on some semi-supervised objective. Move the BERT-LMAO objective out from spacy/cli/pretrain.py into spacy/_ml.py, so we can create a new pipeline component, ClozeMultitask. This can be specified as a parser or NER multitask in the spacy train command. Example usage: python -m spacy train en ./tmp ~/data/en-core-web/train/nw.json ~/data/en-core-web/dev/nw.json --pipeline parser --raw-textt ~/data/unlabelled/reddit-100k.jsonl --vectors en_vectors_web_lg --parser-multitasks cloze Implement rehearsal methods for pipeline components The new --raw-text argument and nlp.rehearse() method also gives us a good place to implement the the idea in the pseudo-rehearsal blog post in the parser. This works as follows: Add a new nlp.resume_training() method. This allocates copies of pre-trained models in the pipeline, setting things up for the rehearsal updates. It also returns an optimizer object. This also greatly reduces confusion around the nlp.begin_training() method, which randomises the weights, making it not suitable for adding new labels or otherwise fine-tuning a pre-trained model. Implement rehearsal updates on the Parser class, making it available for the dependency parser and NER. During rehearsal, the initial model is used to supervise the model being trained. The current model is asked to match the predictions of the initial model on some data. This minimises catastrophic forgetting, by keeping the model's predictions close to the original. See the blog post for details. Implement rehearsal updates for tagger Implement rehearsal updates for text categoriz
2018-12-10 18:25:33 +03:00
if losses is not None and self.name not in losses:
losses[self.name] = 0.
predictions, bp_predictions = self.model.begin_update(docs, drop=drop)
loss, d_predictions = self.get_loss(docs, self.vocab.vectors.data, predictions)
bp_predictions(d_predictions, sgd=sgd)
if losses is not None:
losses[self.name] += loss
2017-10-26 13:40:40 +03:00
class TextCategorizer(Pipe):
"""Pipeline component for text classification.
DOCS: https://spacy.io/api/textcategorizer
"""
2017-07-22 02:14:07 +03:00
name = 'textcat'
@classmethod
def Model(cls, nr_class=1, **cfg):
embed_size = util.env_opt("embed_size", 2000)
if "token_vector_width" in cfg:
token_vector_width = cfg["token_vector_width"]
else:
token_vector_width = util.env_opt("token_vector_width", 96)
if cfg.get("architecture") == "simple_cnn":
tok2vec = Tok2Vec(token_vector_width, embed_size, **cfg)
return build_simple_cnn_text_classifier(tok2vec, nr_class, **cfg)
else:
return build_text_classifier(nr_class, **cfg)
2018-11-03 01:51:37 +03:00
@property
def tok2vec(self):
if self.model in (None, True, False):
return None
else:
return self.model.tok2vec
2018-11-03 01:51:37 +03:00
def __init__(self, vocab, model=True, **cfg):
self.vocab = vocab
self.model = model
💫 Better support for semi-supervised learning (#3035) The new spacy pretrain command implemented BERT/ULMFit/etc-like transfer learning, using our Language Modelling with Approximate Outputs version of BERT's cloze task. Pretraining is convenient, but in some ways it's a bit of a strange solution. All we're doing is initialising the weights. At the same time, we're putting a lot of work into our optimisation so that it's less sensitive to initial conditions, and more likely to find good optima. I discuss this a bit in the pseudo-rehearsal blog post: https://explosion.ai/blog/pseudo-rehearsal-catastrophic-forgetting Support semi-supervised learning in spacy train One obvious way to improve these pretraining methods is to do multi-task learning, instead of just transfer learning. This has been shown to work very well: https://arxiv.org/pdf/1809.08370.pdf . This patch makes it easy to do this sort of thing. Add a new argument to spacy train, --raw-text. This takes a jsonl file with unlabelled data that can be used in arbitrary ways to do semi-supervised learning. Add a new method to the Language class and to pipeline components, .rehearse(). This is like .update(), but doesn't expect GoldParse objects. It takes a batch of Doc objects, and performs an update on some semi-supervised objective. Move the BERT-LMAO objective out from spacy/cli/pretrain.py into spacy/_ml.py, so we can create a new pipeline component, ClozeMultitask. This can be specified as a parser or NER multitask in the spacy train command. Example usage: python -m spacy train en ./tmp ~/data/en-core-web/train/nw.json ~/data/en-core-web/dev/nw.json --pipeline parser --raw-textt ~/data/unlabelled/reddit-100k.jsonl --vectors en_vectors_web_lg --parser-multitasks cloze Implement rehearsal methods for pipeline components The new --raw-text argument and nlp.rehearse() method also gives us a good place to implement the the idea in the pseudo-rehearsal blog post in the parser. This works as follows: Add a new nlp.resume_training() method. This allocates copies of pre-trained models in the pipeline, setting things up for the rehearsal updates. It also returns an optimizer object. This also greatly reduces confusion around the nlp.begin_training() method, which randomises the weights, making it not suitable for adding new labels or otherwise fine-tuning a pre-trained model. Implement rehearsal updates on the Parser class, making it available for the dependency parser and NER. During rehearsal, the initial model is used to supervise the model being trained. The current model is asked to match the predictions of the initial model on some data. This minimises catastrophic forgetting, by keeping the model's predictions close to the original. See the blog post for details. Implement rehearsal updates for tagger Implement rehearsal updates for text categoriz
2018-12-10 18:25:33 +03:00
self._rehearsal_model = None
2017-07-23 01:52:47 +03:00
self.cfg = dict(cfg)
2017-07-23 01:33:43 +03:00
@property
def labels(self):
return tuple(self.cfg.setdefault("labels", []))
2017-07-23 01:33:43 +03:00
@labels.setter
def labels(self, value):
self.cfg["labels"] = tuple(value)
def __call__(self, doc):
2017-11-03 13:20:05 +03:00
scores, tensors = self.predict([doc])
self.set_annotations([doc], scores, tensors=tensors)
return doc
def pipe(self, stream, batch_size=128, n_threads=-1):
2018-12-03 04:19:12 +03:00
for docs in util.minibatch(stream, size=batch_size):
docs = list(docs)
2017-11-03 13:20:05 +03:00
scores, tensors = self.predict(docs)
self.set_annotations(docs, scores, tensors=tensors)
yield from docs
def predict(self, docs):
self.require_model()
scores = self.model(docs)
scores = self.model.ops.asarray(scores)
2017-11-05 14:25:10 +03:00
tensors = [doc.tensor for doc in docs]
return scores, tensors
2017-11-03 13:20:05 +03:00
def set_annotations(self, docs, scores, tensors=None):
for i, doc in enumerate(docs):
for j, label in enumerate(self.labels):
doc.cats[label] = float(scores[i, j])
def update(self, docs, golds, state=None, drop=0., sgd=None, losses=None):
scores, bp_scores = self.model.begin_update(docs, drop=drop)
loss, d_scores = self.get_loss(docs, golds, scores)
bp_scores(d_scores, sgd=sgd)
if losses is not None:
losses.setdefault(self.name, 0.0)
losses[self.name] += loss
💫 Better support for semi-supervised learning (#3035) The new spacy pretrain command implemented BERT/ULMFit/etc-like transfer learning, using our Language Modelling with Approximate Outputs version of BERT's cloze task. Pretraining is convenient, but in some ways it's a bit of a strange solution. All we're doing is initialising the weights. At the same time, we're putting a lot of work into our optimisation so that it's less sensitive to initial conditions, and more likely to find good optima. I discuss this a bit in the pseudo-rehearsal blog post: https://explosion.ai/blog/pseudo-rehearsal-catastrophic-forgetting Support semi-supervised learning in spacy train One obvious way to improve these pretraining methods is to do multi-task learning, instead of just transfer learning. This has been shown to work very well: https://arxiv.org/pdf/1809.08370.pdf . This patch makes it easy to do this sort of thing. Add a new argument to spacy train, --raw-text. This takes a jsonl file with unlabelled data that can be used in arbitrary ways to do semi-supervised learning. Add a new method to the Language class and to pipeline components, .rehearse(). This is like .update(), but doesn't expect GoldParse objects. It takes a batch of Doc objects, and performs an update on some semi-supervised objective. Move the BERT-LMAO objective out from spacy/cli/pretrain.py into spacy/_ml.py, so we can create a new pipeline component, ClozeMultitask. This can be specified as a parser or NER multitask in the spacy train command. Example usage: python -m spacy train en ./tmp ~/data/en-core-web/train/nw.json ~/data/en-core-web/dev/nw.json --pipeline parser --raw-textt ~/data/unlabelled/reddit-100k.jsonl --vectors en_vectors_web_lg --parser-multitasks cloze Implement rehearsal methods for pipeline components The new --raw-text argument and nlp.rehearse() method also gives us a good place to implement the the idea in the pseudo-rehearsal blog post in the parser. This works as follows: Add a new nlp.resume_training() method. This allocates copies of pre-trained models in the pipeline, setting things up for the rehearsal updates. It also returns an optimizer object. This also greatly reduces confusion around the nlp.begin_training() method, which randomises the weights, making it not suitable for adding new labels or otherwise fine-tuning a pre-trained model. Implement rehearsal updates on the Parser class, making it available for the dependency parser and NER. During rehearsal, the initial model is used to supervise the model being trained. The current model is asked to match the predictions of the initial model on some data. This minimises catastrophic forgetting, by keeping the model's predictions close to the original. See the blog post for details. Implement rehearsal updates for tagger Implement rehearsal updates for text categoriz
2018-12-10 18:25:33 +03:00
def rehearse(self, docs, drop=0., sgd=None, losses=None):
if self._rehearsal_model is None:
return
scores, bp_scores = self.model.begin_update(docs, drop=drop)
target = self._rehearsal_model(docs)
gradient = scores - target
bp_scores(gradient, sgd=sgd)
if losses is not None:
losses.setdefault(self.name, 0.0)
losses[self.name] += (gradient**2).sum()
def get_loss(self, docs, golds, scores):
truths = numpy.zeros((len(golds), len(self.labels)), dtype="f")
not_missing = numpy.ones((len(golds), len(self.labels)), dtype="f")
for i, gold in enumerate(golds):
for j, label in enumerate(self.labels):
if label in gold.cats:
truths[i, j] = gold.cats[label]
else:
not_missing[i, j] = 0.
truths = self.model.ops.asarray(truths)
not_missing = self.model.ops.asarray(not_missing)
d_scores = (scores-truths) / scores.shape[0]
d_scores *= not_missing
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mean_square_error = (d_scores**2).sum(axis=1).mean()
return float(mean_square_error), d_scores
def add_label(self, label):
if label in self.labels:
return 0
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if self.model not in (None, True, False):
# This functionality was available previously, but was broken.
# The problem is that we resize the last layer, but the last layer
# is actually just an ensemble. We're not resizing the child layers
# - a huge problem.
raise ValueError(Errors.E116)
# smaller = self.model._layers[-1]
# larger = Affine(len(self.labels)+1, smaller.nI)
# copy_array(larger.W[:smaller.nO], smaller.W)
# copy_array(larger.b[:smaller.nO], smaller.b)
# self.model._layers[-1] = larger
self.labels = tuple(list(self.labels) + [label])
return 1
def begin_training(self, get_gold_tuples=lambda: [], pipeline=None, sgd=None, **kwargs):
if self.model is True:
self.cfg["pretrained_vectors"] = kwargs.get("pretrained_vectors")
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self.model = self.Model(len(self.labels), **self.cfg)
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link_vectors_to_models(self.vocab)
if sgd is None:
sgd = self.create_optimizer()
return sgd
cdef class DependencyParser(Parser):
"""Pipeline component for dependency parsing.
DOCS: https://spacy.io/api/dependencyparser
"""
name = "parser"
TransitionSystem = ArcEager
@property
def postprocesses(self):
return [nonproj.deprojectivize]
def add_multitask_objective(self, target):
if target == "cloze":
💫 Better support for semi-supervised learning (#3035) The new spacy pretrain command implemented BERT/ULMFit/etc-like transfer learning, using our Language Modelling with Approximate Outputs version of BERT's cloze task. Pretraining is convenient, but in some ways it's a bit of a strange solution. All we're doing is initialising the weights. At the same time, we're putting a lot of work into our optimisation so that it's less sensitive to initial conditions, and more likely to find good optima. I discuss this a bit in the pseudo-rehearsal blog post: https://explosion.ai/blog/pseudo-rehearsal-catastrophic-forgetting Support semi-supervised learning in spacy train One obvious way to improve these pretraining methods is to do multi-task learning, instead of just transfer learning. This has been shown to work very well: https://arxiv.org/pdf/1809.08370.pdf . This patch makes it easy to do this sort of thing. Add a new argument to spacy train, --raw-text. This takes a jsonl file with unlabelled data that can be used in arbitrary ways to do semi-supervised learning. Add a new method to the Language class and to pipeline components, .rehearse(). This is like .update(), but doesn't expect GoldParse objects. It takes a batch of Doc objects, and performs an update on some semi-supervised objective. Move the BERT-LMAO objective out from spacy/cli/pretrain.py into spacy/_ml.py, so we can create a new pipeline component, ClozeMultitask. This can be specified as a parser or NER multitask in the spacy train command. Example usage: python -m spacy train en ./tmp ~/data/en-core-web/train/nw.json ~/data/en-core-web/dev/nw.json --pipeline parser --raw-textt ~/data/unlabelled/reddit-100k.jsonl --vectors en_vectors_web_lg --parser-multitasks cloze Implement rehearsal methods for pipeline components The new --raw-text argument and nlp.rehearse() method also gives us a good place to implement the the idea in the pseudo-rehearsal blog post in the parser. This works as follows: Add a new nlp.resume_training() method. This allocates copies of pre-trained models in the pipeline, setting things up for the rehearsal updates. It also returns an optimizer object. This also greatly reduces confusion around the nlp.begin_training() method, which randomises the weights, making it not suitable for adding new labels or otherwise fine-tuning a pre-trained model. Implement rehearsal updates on the Parser class, making it available for the dependency parser and NER. During rehearsal, the initial model is used to supervise the model being trained. The current model is asked to match the predictions of the initial model on some data. This minimises catastrophic forgetting, by keeping the model's predictions close to the original. See the blog post for details. Implement rehearsal updates for tagger Implement rehearsal updates for text categoriz
2018-12-10 18:25:33 +03:00
cloze = ClozeMultitask(self.vocab)
self._multitasks.append(cloze)
else:
labeller = MultitaskObjective(self.vocab, target=target)
self._multitasks.append(labeller)
def init_multitask_objectives(self, get_gold_tuples, pipeline, sgd=None, **cfg):
for labeller in self._multitasks:
2018-09-13 15:08:55 +03:00
tok2vec = self.model.tok2vec
labeller.begin_training(get_gold_tuples, pipeline=pipeline,
tok2vec=tok2vec, sgd=sgd)
def __reduce__(self):
return (DependencyParser, (self.vocab, self.moves, self.model), None, None)
@property
def labels(self):
# Get the labels from the model by looking at the available moves
return tuple(set(move.split("-")[1] for move in self.move_names))
cdef class EntityRecognizer(Parser):
"""Pipeline component for named entity recognition.
DOCS: https://spacy.io/api/entityrecognizer
"""
name = "ner"
TransitionSystem = BiluoPushDown
nr_feature = 6
def add_multitask_objective(self, target):
if target == "cloze":
💫 Better support for semi-supervised learning (#3035) The new spacy pretrain command implemented BERT/ULMFit/etc-like transfer learning, using our Language Modelling with Approximate Outputs version of BERT's cloze task. Pretraining is convenient, but in some ways it's a bit of a strange solution. All we're doing is initialising the weights. At the same time, we're putting a lot of work into our optimisation so that it's less sensitive to initial conditions, and more likely to find good optima. I discuss this a bit in the pseudo-rehearsal blog post: https://explosion.ai/blog/pseudo-rehearsal-catastrophic-forgetting Support semi-supervised learning in spacy train One obvious way to improve these pretraining methods is to do multi-task learning, instead of just transfer learning. This has been shown to work very well: https://arxiv.org/pdf/1809.08370.pdf . This patch makes it easy to do this sort of thing. Add a new argument to spacy train, --raw-text. This takes a jsonl file with unlabelled data that can be used in arbitrary ways to do semi-supervised learning. Add a new method to the Language class and to pipeline components, .rehearse(). This is like .update(), but doesn't expect GoldParse objects. It takes a batch of Doc objects, and performs an update on some semi-supervised objective. Move the BERT-LMAO objective out from spacy/cli/pretrain.py into spacy/_ml.py, so we can create a new pipeline component, ClozeMultitask. This can be specified as a parser or NER multitask in the spacy train command. Example usage: python -m spacy train en ./tmp ~/data/en-core-web/train/nw.json ~/data/en-core-web/dev/nw.json --pipeline parser --raw-textt ~/data/unlabelled/reddit-100k.jsonl --vectors en_vectors_web_lg --parser-multitasks cloze Implement rehearsal methods for pipeline components The new --raw-text argument and nlp.rehearse() method also gives us a good place to implement the the idea in the pseudo-rehearsal blog post in the parser. This works as follows: Add a new nlp.resume_training() method. This allocates copies of pre-trained models in the pipeline, setting things up for the rehearsal updates. It also returns an optimizer object. This also greatly reduces confusion around the nlp.begin_training() method, which randomises the weights, making it not suitable for adding new labels or otherwise fine-tuning a pre-trained model. Implement rehearsal updates on the Parser class, making it available for the dependency parser and NER. During rehearsal, the initial model is used to supervise the model being trained. The current model is asked to match the predictions of the initial model on some data. This minimises catastrophic forgetting, by keeping the model's predictions close to the original. See the blog post for details. Implement rehearsal updates for tagger Implement rehearsal updates for text categoriz
2018-12-10 18:25:33 +03:00
cloze = ClozeMultitask(self.vocab)
self._multitasks.append(cloze)
else:
labeller = MultitaskObjective(self.vocab, target=target)
self._multitasks.append(labeller)
def init_multitask_objectives(self, get_gold_tuples, pipeline, sgd=None, **cfg):
for labeller in self._multitasks:
2018-09-13 15:08:55 +03:00
tok2vec = self.model.tok2vec
labeller.begin_training(get_gold_tuples, pipeline=pipeline,
2017-10-27 21:29:08 +03:00
tok2vec=tok2vec)
def __reduce__(self):
2017-10-27 21:29:08 +03:00
return (EntityRecognizer, (self.vocab, self.moves, self.model),
None, None)
2018-11-18 02:06:26 +03:00
@property
def labels(self):
# Get the labels from the model by looking at the available moves, e.g.
# B-PERSON, I-PERSON, L-PERSON, U-PERSON
return tuple(set(move.split("-")[1] for move in self.move_names
if move[0] in ("B", "I", "L", "U")))
2018-11-18 02:06:26 +03:00
2017-03-15 17:27:41 +03:00
__all__ = ["Tagger", "DependencyParser", "EntityRecognizer", "Tensorizer", "TextCategorizer"]