import ujson from thinc.v2v import Model, Maxout, Softmax, Affine, ReLu, SELU from thinc.i2v import HashEmbed, StaticVectors from thinc.t2t import ExtractWindow, ParametricAttention from thinc.t2v import Pooling, max_pool, mean_pool, sum_pool from thinc.misc import Residual from thinc.misc import BatchNorm as BN from thinc.misc import LayerNorm as LN from thinc.api import add, layerize, chain, clone, concatenate, with_flatten from thinc.api import FeatureExtracter, with_getitem from thinc.api import uniqued, wrap, flatten_add_lengths, noop from thinc.linear.linear import LinearModel from thinc.neural.ops import NumpyOps, CupyOps from thinc.neural.util import get_array_module import random import cytoolz from thinc import describe from thinc.describe import Dimension, Synapses, Biases, Gradient from thinc.neural._classes.affine import _set_dimensions_if_needed import thinc.extra.load_nlp from .attrs import ID, ORTH, LOWER, NORM, PREFIX, SUFFIX, SHAPE, TAG, DEP, CLUSTER from .tokens.doc import Doc from . import util import numpy import io # TODO: Unset this once we don't want to support models previous models. import thinc.neural._classes.layernorm thinc.neural._classes.layernorm.set_compat_six_eight(False) VECTORS_KEY = 'spacy_pretrained_vectors' @layerize def _flatten_add_lengths(seqs, pad=0, drop=0.): ops = Model.ops lengths = ops.asarray([len(seq) for seq in seqs], dtype='i') def finish_update(d_X, sgd=None): return ops.unflatten(d_X, lengths, pad=pad) X = ops.flatten(seqs, pad=pad) return (X, lengths), finish_update @layerize def _logistic(X, drop=0.): xp = get_array_module(X) if not isinstance(X, xp.ndarray): X = xp.asarray(X) # Clip to range (-10, 10) X = xp.minimum(X, 10., X) X = xp.maximum(X, -10., X) Y = 1. / (1. + xp.exp(-X)) def logistic_bwd(dY, sgd=None): dX = dY * (Y * (1-Y)) return dX return Y, logistic_bwd @layerize def add_tuples(X, drop=0.): """Give inputs of sequence pairs, where each sequence is (vals, length), sum the values, returning a single sequence. If input is: ((vals1, length), (vals2, length) Output is: (vals1+vals2, length) vals are a single tensor for the whole batch. """ (vals1, length1), (vals2, length2) = X assert length1 == length2 def add_tuples_bwd(dY, sgd=None): return (dY, dY) return (vals1+vals2, length), add_tuples_bwd def _zero_init(model): def _zero_init_impl(self, X, y): self.W.fill(0) model.on_data_hooks.append(_zero_init_impl) if model.W is not None: model.W.fill(0.) return model @layerize def _preprocess_doc(docs, drop=0.): keys = [doc.to_array([LOWER]) for doc in docs] keys = [a[:, 0] for a in keys] ops = Model.ops lengths = ops.asarray([arr.shape[0] for arr in keys]) keys = ops.xp.concatenate(keys) vals = ops.allocate(keys.shape[0]) + 1 return (keys, vals, lengths), None def _init_for_precomputed(W, ops): if (W**2).sum() != 0.: return reshaped = W.reshape((W.shape[1], W.shape[0] * W.shape[2])) ops.xavier_uniform_init(reshaped) W[:] = reshaped.reshape(W.shape) @describe.on_data(_set_dimensions_if_needed) @describe.attributes( nI=Dimension("Input size"), nF=Dimension("Number of features"), nO=Dimension("Output size"), W=Synapses("Weights matrix", lambda obj: (obj.nF, obj.nO, obj.nI), lambda W, ops: _init_for_precomputed(W, ops)), b=Biases("Bias vector", lambda obj: (obj.nO,)), d_W=Gradient("W"), d_b=Gradient("b") ) class PrecomputableAffine(Model): def __init__(self, nO=None, nI=None, nF=None, **kwargs): Model.__init__(self, **kwargs) self.nO = nO self.nI = nI self.nF = nF def begin_update(self, X, drop=0.): # X: (b, i) # Yf: (b, f, i) # dY: (b, o) # dYf: (b, f, o) #Yf = numpy.einsum('bi,foi->bfo', X, self.W) Yf = self.ops.xp.tensordot( X, self.W, axes=[[1], [2]]) Yf += self.b def backward(dY_ids, sgd=None): tensordot = self.ops.xp.tensordot dY, ids = dY_ids Xf = X[ids] #dXf = numpy.einsum('bo,foi->bfi', dY, self.W) dXf = tensordot(dY, self.W, axes=[[1], [1]]) #dW = numpy.einsum('bo,bfi->ofi', dY, Xf) dW = tensordot(dY, Xf, axes=[[0], [0]]) # ofi -> foi self.d_W += dW.transpose((1, 0, 2)) self.d_b += dY.sum(axis=0) if sgd is not None: sgd(self._mem.weights, self._mem.gradient, key=self.id) return dXf return Yf, backward @describe.on_data(_set_dimensions_if_needed) @describe.attributes( nI=Dimension("Input size"), nF=Dimension("Number of features"), nP=Dimension("Number of pieces"), nO=Dimension("Output size"), W=Synapses("Weights matrix", lambda obj: (obj.nF, obj.nO, obj.nP, obj.nI), lambda W, ops: ops.xavier_uniform_init(W)), b=Biases("Bias vector", lambda obj: (obj.nO, obj.nP)), d_W=Gradient("W"), d_b=Gradient("b") ) class PrecomputableMaxouts(Model): def __init__(self, nO=None, nI=None, nF=None, nP=3, **kwargs): Model.__init__(self, **kwargs) self.nO = nO self.nP = nP self.nI = nI self.nF = nF def begin_update(self, X, drop=0.): # X: (b, i) # Yfp: (b, f, o, p) # Xf: (f, b, i) # dYp: (b, o, p) # W: (f, o, p, i) # b: (o, p) # bi,opfi->bfop # bop,fopi->bfi # bop,fbi->opfi : fopi tensordot = self.ops.xp.tensordot ascontiguous = self.ops.xp.ascontiguousarray Yfp = tensordot(X, self.W, axes=[[1], [3]]) Yfp += self.b def backward(dYp_ids, sgd=None): dYp, ids = dYp_ids Xf = X[ids] dXf = tensordot(dYp, self.W, axes=[[1, 2], [1,2]]) dW = tensordot(dYp, Xf, axes=[[0], [0]]) self.d_W += dW.transpose((2, 0, 1, 3)) self.d_b += dYp.sum(axis=0) if sgd is not None: sgd(self._mem.weights, self._mem.gradient, key=self.id) return dXf return Yfp, backward # Thinc's Embed class is a bit broken atm, so drop this here. from thinc import describe from thinc.neural._classes.embed import _uniform_init @describe.attributes( nV=describe.Dimension("Number of vectors"), nO=describe.Dimension("Size of output"), vectors=describe.Weights("Embedding table", lambda obj: (obj.nV, obj.nO), _uniform_init(-0.1, 0.1) ), d_vectors=describe.Gradient("vectors") ) class Embed(Model): name = 'embed' def __init__(self, nO, nV=None, **kwargs): if nV is not None: nV += 1 Model.__init__(self, **kwargs) if 'name' in kwargs: self.name = kwargs['name'] self.column = kwargs.get('column', 0) self.nO = nO self.nV = nV def predict(self, ids): if ids.ndim == 2: ids = ids[:, self.column] return self.ops.xp.ascontiguousarray(self.vectors[ids], dtype='f') def begin_update(self, ids, drop=0.): if ids.ndim == 2: ids = ids[:, self.column] vectors = self.ops.xp.ascontiguousarray(self.vectors[ids], dtype='f') def backprop_embed(d_vectors, sgd=None): n_vectors = d_vectors.shape[0] self.ops.scatter_add(self.d_vectors, ids, d_vectors) if sgd is not None: sgd(self._mem.weights, self._mem.gradient, key=self.id) return None return vectors, backprop_embed def HistoryFeatures(nr_class, hist_size=8, nr_dim=8): '''Wrap a model, adding features representing action history.''' if hist_size == 0: return layerize(noop()) embed_tables = [Embed(nr_dim, nr_class, column=i, name='embed%d') for i in range(hist_size)] embed = chain(concatenate(*embed_tables), LN(Maxout(hist_size*nr_dim, hist_size*nr_dim))) ops = embed.ops def add_history_fwd(vectors_hists, drop=0.): vectors, hist_ids = vectors_hists hist_feats, bp_hists = embed.begin_update(hist_ids, drop=drop) outputs = ops.xp.hstack((vectors, hist_feats)) def add_history_bwd(d_outputs, sgd=None): d_vectors = d_outputs[:, :vectors.shape[1]] d_hists = d_outputs[:, vectors.shape[1]:] bp_hists(d_hists, sgd=sgd) return embed.ops.xp.ascontiguousarray(d_vectors) return outputs, add_history_bwd return wrap(add_history_fwd, embed) def drop_layer(layer, factor=2.): def drop_layer_fwd(X, drop=0.): if drop <= 0.: return layer.begin_update(X, drop=drop) else: coinflip = layer.ops.xp.random.random() if (coinflip / factor) >= drop: return layer.begin_update(X, drop=drop) else: return X, lambda dX, sgd=None: dX model = wrap(drop_layer_fwd, layer) model.predict = layer return model def link_vectors_to_models(vocab): vectors = vocab.vectors ops = Model.ops for word in vocab: if word.orth in vectors.key2row: word.rank = vectors.key2row[word.orth] else: word.rank = 0 data = ops.asarray(vectors.data) # Set an entry here, so that vectors are accessed by StaticVectors # (unideal, I know) thinc.extra.load_nlp.VECTORS[(ops.device, VECTORS_KEY)] = data def Tok2Vec(width, embed_size, **kwargs): pretrained_dims = kwargs.get('pretrained_dims', 0) cnn_maxout_pieces = kwargs.get('cnn_maxout_pieces', 2) cols = [ID, NORM, PREFIX, SUFFIX, SHAPE, ORTH] with Model.define_operators({'>>': chain, '|': concatenate, '**': clone, '+': add, '*': reapply}): norm = HashEmbed(width, embed_size, column=cols.index(NORM), name='embed_norm') prefix = HashEmbed(width, embed_size//2, column=cols.index(PREFIX), name='embed_prefix') suffix = HashEmbed(width, embed_size//2, column=cols.index(SUFFIX), name='embed_suffix') shape = HashEmbed(width, embed_size//2, column=cols.index(SHAPE), name='embed_shape') if pretrained_dims is not None and pretrained_dims >= 1: glove = StaticVectors(VECTORS_KEY, width, column=cols.index(ID)) embed = uniqued( (glove | norm | prefix | suffix | shape) >> LN(Maxout(width, width*5, pieces=3)), column=5) else: embed = uniqued( (norm | prefix | suffix | shape) >> LN(Maxout(width, width*4, pieces=3)), column=5) convolution = Residual( ExtractWindow(nW=1) >> LN(Maxout(width, width*3, pieces=cnn_maxout_pieces)) ) tok2vec = ( FeatureExtracter(cols) >> with_flatten( embed >> (convolution ** 4), pad=4) ) # Work around thinc API limitations :(. TODO: Revise in Thinc 7 tok2vec.nO = width tok2vec.embed = embed return tok2vec def reapply(layer, n_times): def reapply_fwd(X, drop=0.): backprops = [] for i in range(n_times): Y, backprop = layer.begin_update(X, drop=drop) X = Y backprops.append(backprop) def reapply_bwd(dY, sgd=None): dX = None for backprop in reversed(backprops): dY = backprop(dY, sgd=sgd) if dX is None: dX = dY else: dX += dY return dX return Y, reapply_bwd return wrap(reapply_fwd, layer) def asarray(ops, dtype): def forward(X, drop=0.): return ops.asarray(X, dtype=dtype), None return layerize(forward) def foreach(layer): def forward(Xs, drop=0.): results = [] backprops = [] for X in Xs: result, bp = layer.begin_update(X, drop=drop) results.append(result) backprops.append(bp) def backward(d_results, sgd=None): dXs = [] for d_result, backprop in zip(d_results, backprops): dXs.append(backprop(d_result, sgd)) return dXs return results, backward model = layerize(forward) model._layers.append(layer) return model def rebatch(size, layer): ops = layer.ops def forward(X, drop=0.): if X.shape[0] < size: return layer.begin_update(X) parts = _divide_array(X, size) results, bp_results = zip(*[layer.begin_update(p, drop=drop) for p in parts]) y = ops.flatten(results) def backward(dy, sgd=None): d_parts = [bp(y, sgd=sgd) for bp, y in zip(bp_results, _divide_array(dy, size))] try: dX = ops.flatten(d_parts) except TypeError: dX = None except ValueError: dX = None return dX return y, backward model = layerize(forward) model._layers.append(layer) return model def _divide_array(X, size): parts = [] index = 0 while index < len(X): parts.append(X[index : index + size]) index += size return parts def get_col(idx): assert idx >= 0, idx def forward(X, drop=0.): assert idx >= 0, idx if isinstance(X, numpy.ndarray): ops = NumpyOps() else: ops = CupyOps() output = ops.xp.ascontiguousarray(X[:, idx], dtype=X.dtype) def backward(y, sgd=None): assert idx >= 0, idx dX = ops.allocate(X.shape) dX[:, idx] += y return dX return output, backward return layerize(forward) def zero_init(model): def _hook(self, X, y=None): self.W.fill(0) model.on_data_hooks.append(_hook) return model def doc2feats(cols=None): if cols is None: cols = [ID, NORM, PREFIX, SUFFIX, SHAPE, ORTH] def forward(docs, drop=0.): feats = [] for doc in docs: feats.append(doc.to_array(cols)) return feats, None model = layerize(forward) model.cols = cols return model def print_shape(prefix): def forward(X, drop=0.): return X, lambda dX, **kwargs: dX return layerize(forward) @layerize def get_token_vectors(tokens_attrs_vectors, drop=0.): ops = Model.ops tokens, attrs, vectors = tokens_attrs_vectors def backward(d_output, sgd=None): return (tokens, d_output) return vectors, backward @layerize def flatten(seqs, drop=0.): if isinstance(seqs[0], numpy.ndarray): ops = NumpyOps() elif hasattr(CupyOps.xp, 'ndarray') and isinstance(seqs[0], CupyOps.xp.ndarray): ops = CupyOps() else: raise ValueError("Unable to flatten sequence of type %s" % type(seqs[0])) lengths = [len(seq) for seq in seqs] def finish_update(d_X, sgd=None): return ops.unflatten(d_X, lengths) X = ops.xp.vstack(seqs) return X, finish_update @layerize def logistic(X, drop=0.): xp = get_array_module(X) if not isinstance(X, xp.ndarray): X = xp.asarray(X) # Clip to range (-10, 10) X = xp.minimum(X, 10., X) X = xp.maximum(X, -10., X) Y = 1. / (1. + xp.exp(-X)) def logistic_bwd(dY, sgd=None): dX = dY * (Y * (1-Y)) return dX return Y, logistic_bwd def zero_init(model): def _zero_init_impl(self, X, y): self.W.fill(0) model.on_data_hooks.append(_zero_init_impl) return model @layerize def preprocess_doc(docs, drop=0.): keys = [doc.to_array([LOWER]) for doc in docs] keys = [a[:, 0] for a in keys] ops = Model.ops lengths = ops.asarray([arr.shape[0] for arr in keys]) keys = ops.xp.concatenate(keys) vals = ops.allocate(keys.shape[0]) + 1 return (keys, vals, lengths), None def getitem(i): def getitem_fwd(X, drop=0.): return X[i], None return layerize(getitem_fwd) def build_tagger_model(nr_class, **cfg): embed_size = util.env_opt('embed_size', 7000) if 'token_vector_width' in cfg: token_vector_width = cfg['token_vector_width'] else: token_vector_width = util.env_opt('token_vector_width', 128) pretrained_dims = cfg.get('pretrained_dims', 0) with Model.define_operators({'>>': chain, '+': add}): if 'tok2vec' in cfg: tok2vec = cfg['tok2vec'] else: tok2vec = Tok2Vec(token_vector_width, embed_size, pretrained_dims=pretrained_dims) model = ( tok2vec >> with_flatten(Softmax(nr_class, token_vector_width)) ) model.nI = None model.tok2vec = tok2vec return model @layerize def SpacyVectors(docs, drop=0.): xp = get_array_module(docs[0].vocab.vectors.data) width = docs[0].vocab.vectors.data.shape[1] batch = [] for doc in docs: indices = numpy.zeros((len(doc),), dtype='i') for i, word in enumerate(doc): if word.orth in doc.vocab.vectors.key2row: indices[i] = doc.vocab.vectors.key2row[word.orth] else: indices[i] = 0 vectors = doc.vocab.vectors.data[indices] batch.append(vectors) return batch, None def foreach(layer, drop_factor=1.0): '''Map a layer across elements in a list''' def foreach_fwd(Xs, drop=0.): drop *= drop_factor ys = [] backprops = [] for X in Xs: y, bp_y = layer.begin_update(X, drop=drop) ys.append(y) backprops.append(bp_y) def foreach_bwd(d_ys, sgd=None): d_Xs = [] for d_y, bp_y in zip(d_ys, backprops): if bp_y is not None and bp_y is not None: d_Xs.append(d_y, sgd=sgd) else: d_Xs.append(None) return d_Xs return ys, foreach_bwd model = wrap(foreach_fwd, layer) return model def build_text_classifier(nr_class, width=64, **cfg): nr_vector = cfg.get('nr_vector', 5000) pretrained_dims = cfg.get('pretrained_dims', 0) with Model.define_operators({'>>': chain, '+': add, '|': concatenate, '**': clone}): if cfg.get('low_data'): model = ( SpacyVectors >> flatten_add_lengths >> with_getitem(0, Affine(width, pretrained_dims) ) >> ParametricAttention(width) >> Pooling(sum_pool) >> Residual(ReLu(width, width)) ** 2 >> zero_init(Affine(nr_class, width, drop_factor=0.0)) >> logistic ) return model lower = HashEmbed(width, nr_vector, column=1) prefix = HashEmbed(width//2, nr_vector, column=2) suffix = HashEmbed(width//2, nr_vector, column=3) shape = HashEmbed(width//2, nr_vector, column=4) trained_vectors = ( FeatureExtracter([ORTH, LOWER, PREFIX, SUFFIX, SHAPE, ID]) >> with_flatten( uniqued( (lower | prefix | suffix | shape) >> LN(Maxout(width, width+(width//2)*3)), column=0 ) ) ) if pretrained_dims: static_vectors = ( SpacyVectors >> with_flatten(Affine(width, pretrained_dims)) ) # TODO Make concatenate support lists vectors = concatenate_lists(trained_vectors, static_vectors) vectors_width = width*2 else: vectors = trained_vectors vectors_width = width static_vectors = None cnn_model = ( vectors >> with_flatten( LN(Maxout(width, vectors_width)) >> Residual( (ExtractWindow(nW=1) >> LN(Maxout(width, width*3))) ) ** 2, pad=2 ) >> flatten_add_lengths >> ParametricAttention(width) >> Pooling(sum_pool) >> Residual(zero_init(Maxout(width, width))) >> zero_init(Affine(nr_class, width, drop_factor=0.0)) ) linear_model = ( _preprocess_doc >> LinearModel(nr_class, drop_factor=0.) ) model = ( (linear_model | cnn_model) >> zero_init(Affine(nr_class, nr_class*2, drop_factor=0.0)) >> logistic ) model.nO = nr_class model.lsuv = False return model @layerize def flatten(seqs, drop=0.): ops = Model.ops lengths = ops.asarray([len(seq) for seq in seqs], dtype='i') def finish_update(d_X, sgd=None): return ops.unflatten(d_X, lengths, pad=0) X = ops.flatten(seqs, pad=0) return X, finish_update def concatenate_lists(*layers, **kwargs): # pragma: no cover '''Compose two or more models `f`, `g`, etc, such that their outputs are concatenated, i.e. `concatenate(f, g)(x)` computes `hstack(f(x), g(x))` ''' if not layers: return noop() drop_factor = kwargs.get('drop_factor', 1.0) ops = layers[0].ops layers = [chain(layer, flatten) for layer in layers] concat = concatenate(*layers) def concatenate_lists_fwd(Xs, drop=0.): drop *= drop_factor lengths = ops.asarray([len(X) for X in Xs], dtype='i') flat_y, bp_flat_y = concat.begin_update(Xs, drop=drop) ys = ops.unflatten(flat_y, lengths) def concatenate_lists_bwd(d_ys, sgd=None): return bp_flat_y(ops.flatten(d_ys), sgd=sgd) return ys, concatenate_lists_bwd model = wrap(concatenate_lists_fwd, concat) return model