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253 lines
10 KiB
Cython
253 lines
10 KiB
Cython
"""
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MALT-style dependency parser
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"""
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# cython: profile=True
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# cython: experimental_cpp_class_def=True
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# cython: cdivision=True
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# cython: infer_types=True
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# coding: utf-8
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from __future__ import unicode_literals, print_function
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cimport cython
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from cpython.ref cimport PyObject, Py_INCREF, Py_XDECREF
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from libc.stdint cimport uint32_t, uint64_t
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from libc.string cimport memset, memcpy
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from libc.stdlib cimport rand
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from libc.math cimport log, exp, isnan, isinf
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from cymem.cymem cimport Pool, Address
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from murmurhash.mrmr cimport real_hash64 as hash64
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from thinc.typedefs cimport weight_t, class_t, feat_t, atom_t, hash_t
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from thinc.linear.features cimport ConjunctionExtracter
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from thinc.structs cimport FeatureC, ExampleC
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from thinc.extra.search cimport Beam, MaxViolation
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from thinc.extra.eg cimport Example
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from thinc.extra.mb cimport Minibatch
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from ..structs cimport TokenC
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from ..tokens.doc cimport Doc
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from ..strings cimport StringStore
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from .transition_system cimport TransitionSystem, Transition
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from ..gold cimport GoldParse
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from . import _parse_features
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from ._parse_features cimport CONTEXT_SIZE
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from ._parse_features cimport fill_context
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from .stateclass cimport StateClass
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from .parser cimport Parser
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DEBUG = False
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def set_debug(val):
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global DEBUG
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DEBUG = val
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def get_templates(name):
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pf = _parse_features
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if name == 'ner':
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return pf.ner
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elif name == 'debug':
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return pf.unigrams
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else:
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return (pf.unigrams + pf.s0_n0 + pf.s1_n0 + pf.s1_s0 + pf.s0_n1 + pf.n0_n1 + \
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pf.tree_shape + pf.trigrams)
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cdef int BEAM_WIDTH = 16
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cdef weight_t BEAM_DENSITY = 0.001
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cdef class BeamParser(Parser):
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def __init__(self, *args, **kwargs):
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self.beam_width = kwargs.get('beam_width', BEAM_WIDTH)
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self.beam_density = kwargs.get('beam_density', BEAM_DENSITY)
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Parser.__init__(self, *args, **kwargs)
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cdef int parseC(self, TokenC* tokens, int length, int nr_feat) nogil:
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with gil:
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self._parseC(tokens, length, nr_feat, self.moves.n_moves)
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cdef int _parseC(self, TokenC* tokens, int length, int nr_feat, int nr_class) except -1:
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cdef Beam beam = Beam(self.moves.n_moves, self.beam_width, min_density=self.beam_density)
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# TODO: How do we handle new labels here? This increases nr_class
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beam.initialize(self.moves.init_beam_state, length, tokens)
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beam.check_done(_check_final_state, NULL)
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if beam.is_done:
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_cleanup(beam)
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return 0
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while not beam.is_done:
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self._advance_beam(beam, None, False)
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state = <StateClass>beam.at(0)
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self.moves.finalize_state(state.c)
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for i in range(length):
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tokens[i] = state.c._sent[i]
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_cleanup(beam)
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def update(self, Doc tokens, GoldParse gold_parse, itn=0):
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self.moves.preprocess_gold(gold_parse)
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cdef Beam pred = Beam(self.moves.n_moves, self.beam_width)
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pred.initialize(self.moves.init_beam_state, tokens.length, tokens.c)
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pred.check_done(_check_final_state, NULL)
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# Hack for NER
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for i in range(pred.size):
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stcls = <StateClass>pred.at(i)
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self.moves.initialize_state(stcls.c)
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cdef Beam gold = Beam(self.moves.n_moves, self.beam_width, min_density=0.0)
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gold.initialize(self.moves.init_beam_state, tokens.length, tokens.c)
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gold.check_done(_check_final_state, NULL)
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violn = MaxViolation()
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while not pred.is_done and not gold.is_done:
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# We search separately here, to allow for ambiguity in the gold parse.
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self._advance_beam(pred, gold_parse, False)
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self._advance_beam(gold, gold_parse, True)
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violn.check_crf(pred, gold)
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if pred.loss > 0 and pred.min_score > (gold.score + self.model.time):
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break
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else:
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# The non-monotonic oracle makes it difficult to ensure final costs are
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# correct. Therefore do final correction
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for i in range(pred.size):
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if is_gold(<StateClass>pred.at(i), gold_parse, self.moves.strings):
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pred._states[i].loss = 0.0
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elif pred._states[i].loss == 0.0:
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pred._states[i].loss = 1.0
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violn.check_crf(pred, gold)
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if pred.size < 1:
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raise Exception("No candidates", tokens.length)
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if gold.size < 1:
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raise Exception("No gold", tokens.length)
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if pred.loss == 0:
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self.model.update_from_histories(self.moves, tokens, [(0.0, [])])
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elif True:
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#_check_train_integrity(pred, gold, gold_parse, self.moves)
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histories = list(zip(violn.p_probs, violn.p_hist)) + \
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list(zip(violn.g_probs, violn.g_hist))
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self.model.update_from_histories(self.moves, tokens, histories, min_grad=0.001**(itn+1))
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else:
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self.model.update_from_histories(self.moves, tokens,
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[(1.0, violn.p_hist[0]), (-1.0, violn.g_hist[0])])
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_cleanup(pred)
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_cleanup(gold)
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return pred.loss
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def _advance_beam(self, Beam beam, GoldParse gold, bint follow_gold):
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cdef atom_t[CONTEXT_SIZE] context
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cdef Pool mem = Pool()
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features = <FeatureC*>mem.alloc(self.model.nr_feat, sizeof(FeatureC))
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if False:
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mb = Minibatch(self.model.widths, beam.size)
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for i in range(beam.size):
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stcls = <StateClass>beam.at(i)
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if stcls.c.is_final():
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nr_feat = 0
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else:
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nr_feat = self.model.set_featuresC(context, features, stcls.c)
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self.moves.set_valid(beam.is_valid[i], stcls.c)
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mb.c.push_back(features, nr_feat, beam.costs[i], beam.is_valid[i], 0)
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self.model(mb)
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for i in range(beam.size):
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memcpy(beam.scores[i], mb.c.scores(i), mb.c.nr_out() * sizeof(beam.scores[i][0]))
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else:
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for i in range(beam.size):
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stcls = <StateClass>beam.at(i)
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if not stcls.is_final():
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nr_feat = self.model.set_featuresC(context, features, stcls.c)
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self.moves.set_valid(beam.is_valid[i], stcls.c)
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self.model.set_scoresC(beam.scores[i], features, nr_feat)
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if gold is not None:
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n_gold = 0
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lines = []
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for i in range(beam.size):
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stcls = <StateClass>beam.at(i)
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if not stcls.c.is_final():
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self.moves.set_costs(beam.is_valid[i], beam.costs[i], stcls, gold)
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if follow_gold:
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for j in range(self.moves.n_moves):
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if beam.costs[i][j] >= 1:
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beam.is_valid[i][j] = 0
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lines.append((stcls.B(0), stcls.B(1),
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stcls.B_(0).ent_iob, stcls.B_(1).ent_iob,
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stcls.B_(1).sent_start,
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j,
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beam.is_valid[i][j], 'set invalid',
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beam.costs[i][j], self.moves.c[j].move, self.moves.c[j].label))
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n_gold += 1 if beam.is_valid[i][j] else 0
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if follow_gold and n_gold == 0:
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raise Exception("No gold")
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if follow_gold:
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beam.advance(_transition_state, NULL, <void*>self.moves.c)
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else:
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beam.advance(_transition_state, _hash_state, <void*>self.moves.c)
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beam.check_done(_check_final_state, NULL)
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# These are passed as callbacks to thinc.search.Beam
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cdef int _transition_state(void* _dest, void* _src, class_t clas, void* _moves) except -1:
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dest = <StateClass>_dest
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src = <StateClass>_src
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moves = <const Transition*>_moves
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dest.clone(src)
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moves[clas].do(dest.c, moves[clas].label)
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cdef int _check_final_state(void* _state, void* extra_args) except -1:
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return (<StateClass>_state).is_final()
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def _cleanup(Beam beam):
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for i in range(beam.width):
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Py_XDECREF(<PyObject*>beam._states[i].content)
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Py_XDECREF(<PyObject*>beam._parents[i].content)
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cdef hash_t _hash_state(void* _state, void* _) except 0:
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state = <StateClass>_state
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if state.c.is_final():
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return 1
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else:
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return state.c.hash()
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def _check_train_integrity(Beam pred, Beam gold, GoldParse gold_parse, TransitionSystem moves):
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for i in range(pred.size):
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if not pred._states[i].is_done or pred._states[i].loss == 0:
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continue
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state = <StateClass>pred.at(i)
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if is_gold(state, gold_parse, moves.strings) == True:
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for dep in gold_parse.orig_annot:
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print(dep[1], dep[3], dep[4])
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print("Cost", pred._states[i].loss)
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for j in range(gold_parse.length):
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print(gold_parse.orig_annot[j][1], state.H(j), moves.strings[state.safe_get(j).dep])
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acts = [moves.c[clas].move for clas in pred.histories[i]]
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labels = [moves.c[clas].label for clas in pred.histories[i]]
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print([moves.move_name(move, label) for move, label in zip(acts, labels)])
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raise Exception("Predicted state is gold-standard")
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for i in range(gold.size):
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if not gold._states[i].is_done:
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continue
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state = <StateClass>gold.at(i)
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if is_gold(state, gold_parse, moves.strings) == False:
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print("Truth")
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for dep in gold_parse.orig_annot:
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print(dep[1], dep[3], dep[4])
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print("Predicted good")
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for j in range(gold_parse.length):
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print(gold_parse.orig_annot[j][1], state.H(j), moves.strings[state.safe_get(j).dep])
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raise Exception("Gold parse is not gold-standard")
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def is_gold(StateClass state, GoldParse gold, StringStore strings):
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predicted = set()
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truth = set()
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for i in range(gold.length):
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if gold.cand_to_gold[i] is None:
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continue
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if state.safe_get(i).dep:
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predicted.add((i, state.H(i), strings[state.safe_get(i).dep]))
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else:
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predicted.add((i, state.H(i), 'ROOT'))
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id_, word, tag, head, dep, ner = gold.orig_annot[gold.cand_to_gold[i]]
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truth.add((id_, head, dep))
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return truth == predicted
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