def build_text_classifier_v2(
tok2vec: Model[List[Doc], List[Floats2d]],
linear_model: Model[List[Doc], Floats2d],
nO: Optional[int] = None,
) -> Model[List[Doc], Floats2d]:
exclusive_classes = not linear_model.attrs["multi_label"]
with Model.define_operators({">>": chain, "|": concatenate}):
width = tok2vec.maybe_get_dim("nO")
attention_layer = ParametricAttention(
width) # TODO: benchmark performance difference of this layer
maxout_layer = Maxout(nO=width, nI=width)
norm_layer = LayerNorm(nI=width)
cnn_model = (
tok2vec >> list2ragged() >> attention_layer >> reduce_sum() >>
residual(maxout_layer >> norm_layer >> Dropout(0.0)))
nO_double = nO * 2 if nO else None
if exclusive_classes:
output_layer = Softmax(nO=nO, nI=nO_double)
else:
output_layer = Linear(nO=nO, nI=nO_double) >> Logistic()
model = (linear_model | cnn_model) >> output_layer
model.set_ref("tok2vec", tok2vec)
if model.has_dim("nO") is not False:
model.set_dim("nO", nO)
model.set_ref("output_layer", linear_model.get_ref("output_layer"))
model.set_ref("attention_layer", attention_layer)
model.set_ref("maxout_layer", maxout_layer)
model.set_ref("norm_layer", norm_layer)
model.attrs["multi_label"] = not exclusive_classes
model.init = init_ensemble_textcat
return model
def test_validation_complex():
good_model = chain(list2ragged(), reduce_sum(), Relu(12, dropout=0.5), Relu(1))
X = [good_model.ops.xp.zeros((4, 75), dtype="f")]
Y = good_model.ops.xp.zeros((1,), dtype="f")
good_model.initialize(X, Y)
good_model.predict(X)
bad_model = chain(
list2ragged(),
reduce_sum(),
Relu(12, dropout=0.5),
# ERROR: Why can't I attach a Relu to an attention layer?
ParametricAttention(12),
Relu(1),
)
with pytest.raises(DataValidationError):
bad_model.initialize(X, Y)
def build_text_classifier_lowdata(
width: int,
dropout: Optional[float],
nO: Optional[int] = None) -> Model[List[Doc], Floats2d]:
# Don't document this yet, I'm not sure it's right.
# Note, before v.3, this was the default if setting "low_data" and "pretrained_dims"
with Model.define_operators({">>": chain, "**": clone}):
model = (StaticVectors(width) >> list2ragged() >>
ParametricAttention(width) >> reduce_sum() >> residual(
Relu(width, width))**2 >> Linear(nO, width))
if dropout:
model = model >> Dropout(dropout)
model = model >> Logistic()
return model
def test_reduce_sum(Xs):
model = reduce_sum()
lengths = model.ops.asarray([x.shape[0] for x in Xs], dtype="i")
X = Ragged(model.ops.flatten(Xs), lengths)
Y, backprop = model(X, is_train=True)
assert isinstance(Y, numpy.ndarray)
assert Y.shape == (len(Xs), Xs[0].shape[1])
assert Y.dtype == Xs[0].dtype
assert Y[0][0] == Xs[0][:, 0].sum()
assert numpy.all(Y[0] == Y[0][0])
assert Y[1][-1] == Xs[1][:, 0].sum()
assert numpy.all(Y[1] == Y[1][0])
dX = backprop(Y)
assert dX.dataXd.shape == X.dataXd.shape
def test_init_reduce_sum():
model = reduce_sum()
def TextCatEnsemble_v1(
width: int,
embed_size: int,
pretrained_vectors: Optional[bool],
exclusive_classes: bool,
ngram_size: int,
window_size: int,
conv_depth: int,
dropout: Optional[float],
nO: Optional[int] = None,
) -> Model:
# Don't document this yet, I'm not sure it's right.
cols = [ORTH, LOWER, PREFIX, SUFFIX, SHAPE, ID]
with Model.define_operators({">>": chain, "|": concatenate, "**": clone}):
lower = HashEmbed(nO=width,
nV=embed_size,
column=cols.index(LOWER),
dropout=dropout,
seed=10)
prefix = HashEmbed(
nO=width // 2,
nV=embed_size,
column=cols.index(PREFIX),
dropout=dropout,
seed=11,
)
suffix = HashEmbed(
nO=width // 2,
nV=embed_size,
column=cols.index(SUFFIX),
dropout=dropout,
seed=12,
)
shape = HashEmbed(
nO=width // 2,
nV=embed_size,
column=cols.index(SHAPE),
dropout=dropout,
seed=13,
)
width_nI = sum(
layer.get_dim("nO") for layer in [lower, prefix, suffix, shape])
trained_vectors = FeatureExtractor(cols) >> with_array(
uniqued(
(lower | prefix | suffix | shape) >> Maxout(
nO=width, nI=width_nI, normalize=True),
column=cols.index(ORTH),
))
if pretrained_vectors:
static_vectors = StaticVectors(width)
vector_layer = trained_vectors | static_vectors
vectors_width = width * 2
else:
vector_layer = trained_vectors
vectors_width = width
tok2vec = vector_layer >> with_array(
Maxout(width, vectors_width, normalize=True) >>
residual((expand_window(window_size=window_size) >> Maxout(
nO=width, nI=width *
((window_size * 2) + 1), normalize=True)))**conv_depth,
pad=conv_depth,
)
cnn_model = (tok2vec >> list2ragged() >> ParametricAttention(width) >>
reduce_sum() >> residual(Maxout(nO=width, nI=width)) >>
Linear(nO=nO, nI=width) >> Dropout(0.0))
linear_model = build_bow_text_classifier(
nO=nO,
ngram_size=ngram_size,
exclusive_classes=exclusive_classes,
no_output_layer=False,
)
nO_double = nO * 2 if nO else None
if exclusive_classes:
output_layer = Softmax(nO=nO, nI=nO_double)
else:
output_layer = Linear(nO=nO,
nI=nO_double) >> Dropout(0.0) >> Logistic()
model = (linear_model | cnn_model) >> output_layer
model.set_ref("tok2vec", tok2vec)
if model.has_dim("nO") is not False:
model.set_dim("nO", nO)
model.set_ref("output_layer", linear_model.get_ref("output_layer"))
model.attrs["multi_label"] = not exclusive_classes
return model
