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559 lines
30 KiB
559 lines
30 KiB
import sys
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from copy import copy
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from pyconll.unit import Token
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from Value import Value
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class Tree(object):
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def __init__(self, form, lemma, upos, xpos, deprel, feats, form_dict, lemma_dict, upos_dict, xpos_dict, deprel_dict, feats_dict, feats_complete_dict, head):
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# if not hasattr(self, 'feats'):
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# self.feats = {}
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# form_unicode = str(form).encode("utf-8")
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if form not in form_dict:
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form_dict[form] = Value(form)
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self.form = form_dict[form]
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if lemma not in lemma_dict:
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lemma_dict[lemma] = Value(lemma)
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self.lemma = lemma_dict[lemma]
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if upos not in upos_dict:
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upos_dict[upos] = Value(upos)
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self.upos = upos_dict[upos]
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if xpos not in xpos_dict:
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xpos_dict[xpos] = Value(xpos)
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self.xpos = xpos_dict[xpos]
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if deprel not in deprel_dict:
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deprel_dict[deprel] = Value(deprel)
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self.deprel = deprel_dict[deprel]
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if feats not in feats_complete_dict:
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feats_complete_dict[feats] = Value(feats)
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self.feats_complete = feats_complete_dict[feats]
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# for feat in feats.keys():
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# if next(iter(feats[feat])) not in feats_dict[feat]:
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# feats_dict[feat][next(iter(feats[feat]))] = Value(next(iter(feats[feat])))
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# if not feat in self.feats:
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# self.feats[feat] = {}
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# self.feats[feat][next(iter(feats[feat]))] = feats_dict[feat][next(iter(feats[feat]))]
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# self.position = position
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self.parent = head
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self.children = []
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self.children_split = -1
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self.index = 0
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def add_child(self, child):
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child.index = len(self.children)
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self.children.append(child)
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def set_parent(self, parent):
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self.parent = parent
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# def fits_static_requirements_feats(self, query_tree):
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# if 'feats' not in query_tree:
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# return True
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#
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# for feat in query_tree['feats'].keys():
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# if feat not in self.feats or query_tree['feats'][feat] != next(iter(self.feats[feat].values())).get_value():
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# return False
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#
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# return True
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def fits_static_requirements(self, query_tree):
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return ('form' not in query_tree or query_tree['form'] == self.form.get_value()) and \
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('lemma' not in query_tree or query_tree['lemma'] == self.lemma.get_value()) and \
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('upos' not in query_tree or query_tree['upos'] == self.upos.get_value()) and \
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('xpos' not in query_tree or query_tree['xpos'] == self.xpos.get_value()) and \
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('deprel' not in query_tree or query_tree['deprel'] == self.deprel.get_value()) and \
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('feats' not in query_tree or query_tree['feats'] == self.feats_complete.get_value())
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# self.fits_static_requirements_feats(query_tree)
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def generate_children_queries(self, all_query_indices, children):
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partial_results = {}
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# list of pairs (index of query in group, group of query, is permanent)
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child_queries_metadata = []
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for child_index, child in enumerate(children):
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new_queries = []
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# add continuation queries to children
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for result_part_index, result_index, is_permanent in child_queries_metadata:
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if result_index in partial_results and result_part_index in partial_results[result_index] and len(partial_results[result_index][result_part_index]) > 0:
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if len(all_query_indices[result_index][0]) > result_part_index + 1:
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new_queries.append((result_part_index + 1, result_index, is_permanent))
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# else:
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# completed_subtrees.append((child, result_index))
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child_queries_metadata = new_queries
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# add new queries to children
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for result_index, (group, is_permanent) in enumerate(all_query_indices):
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# check if node has enough children for query to be possible
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if len(children) - len(group) >= child_index:
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child_queries_metadata.append((0, result_index, is_permanent))
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child_queries = []
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for result_part_index, result_index, _ in child_queries_metadata:
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child_queries.append(all_query_indices[result_index][0][result_part_index])
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partial_results = yield child, child_queries, child_queries_metadata
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yield None, None, None
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def add_subtrees(self, old_subtree, new_subtree):
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old_subtree.extend(new_subtree)
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def get_results(self, partial_results_dict, result_index, result_part, outcome, last_result_part):
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# save results for later usage
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# if result index already in and element 0 exists (otherwise error)
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if result_index in partial_results_dict and 0 in partial_results_dict[result_index]:
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if result_part - 1 in partial_results_dict[result_index]:
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if result_part in partial_results_dict[result_index]:
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partial_results_dict[result_index][result_part].extend(self.merge_results(partial_results_dict[result_index][result_part - 1], outcome))
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else:
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partial_results_dict[result_index][result_part] = self.merge_results(partial_results_dict[result_index][result_part - 1], outcome)
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# extend one word layer with output
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else:
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partial_results_dict[result_index][0].extend(outcome)
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else:
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partial_results_dict[result_index] = {0: outcome}
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if last_result_part - 1 in partial_results_dict[result_index]:
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return partial_results_dict[result_index].pop(last_result_part - 1)
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return []
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def group_results(self, new_partial_subtrees, child_queries_metadata, all_query_indices, partial_results_dict, partial_subtrees):
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for outcome, (result_part, result_index, is_permanent) in zip(new_partial_subtrees, child_queries_metadata):
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if outcome:
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new_results = self.get_results(partial_results_dict, result_index, result_part, outcome, len(all_query_indices[result_index][0]))
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if new_results:
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self.add_subtrees(partial_subtrees[result_index], new_results)
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else:
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if not is_permanent:
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partial_subtrees[result_index].append([])
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def get_all_query_indices_old(self, temporary_query_trees_size, completed_subtrees_size, permanent_query_trees, l_all_query_indices, children, create_output_string):
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partial_subtrees = [[] for i in range(completed_subtrees_size + temporary_query_trees_size)]
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completed_subtrees = [[] for i in range(completed_subtrees_size)]
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# list of pairs (index of query in group, group of query)
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partial_results_dict = {}
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children_queries_generator = self.generate_children_queries(l_all_query_indices, children)
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child_index = 0
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child, child_queries, child_queries_metadata = next(children_queries_generator)
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while child:
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# obtain children results
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new_partial_subtrees, new_completed_subtrees = child.get_subtrees(permanent_query_trees, child_queries, create_output_string)
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self.group_results(new_partial_subtrees, child_queries_metadata, l_all_query_indices,
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partial_results_dict, partial_subtrees)
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for i in range(len(new_completed_subtrees)):
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completed_subtrees[i].extend(new_completed_subtrees[i])
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child, child_queries, child_queries_metadata = children_queries_generator.send(partial_results_dict)
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child_index += 1
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return partial_subtrees, completed_subtrees
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def get_all_query_indices(self, temporary_query_trees_size, completed_subtrees_size, permanent_query_trees, all_query_indices, children, create_output_string, filters):
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# l_partial_subtrees, l_completed_subtrees = self.get_all_query_indices(len(temporary_query_trees),
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# len(permanent_query_trees),
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# permanent_query_trees,
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# l_all_query_indices, self.l_children,
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# create_output_string)
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partial_subtrees = [[] for i in range(completed_subtrees_size + temporary_query_trees_size)]
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partial_subtrees_architectures = [[] for i in range(completed_subtrees_size + temporary_query_trees_size)]
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completed_subtrees = [[] for i in range(completed_subtrees_size)]
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# list of pairs (index of query in group, group of query)
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partial_results_dict = {}
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# TODO try to erase!!!
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child_queries = [all_query_indice[0] for all_query_indice in all_query_indices]
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answers_lengths = [len(query) for query in child_queries]
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child_queries_flatten = [query_part for query in child_queries for query_part in query]
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all_new_partial_answers = [[] for query_part in child_queries_flatten]
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all_new_partial_answers_architecture = [[] for query_part in child_queries_flatten]
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# ask children all queries/partial queries
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for child in children:
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# obtain children results
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new_partial_answers_architecture, new_partial_answers, new_completed_subtrees = child.get_subtrees(permanent_query_trees, child_queries_flatten,
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create_output_string, filters)
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assert len(new_partial_answers) == len(child_queries_flatten)
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for i, new_partial_subtree in enumerate(new_partial_answers):
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all_new_partial_answers[i].append(new_partial_subtree)
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all_new_partial_answers_architecture[i].append(new_partial_answers_architecture[i])
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# add 6 queries from 3 split up
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# self.group_results(new_partial_subtrees, child_queries_metadata, all_query_indices,
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# partial_results_dict, partial_subtrees)
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for i in range(len(new_completed_subtrees)):
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completed_subtrees[i].extend(new_completed_subtrees[i])
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# merge answers in appropriate way
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i = 0
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# iterate over all answers per queries
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for answer_i, answer_length in enumerate(answers_lengths):
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# iterate over answers of query
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partial_subtrees[answer_i], partial_subtrees_architectures[answer_i] = self.create_answers(all_new_partial_answers[i:i + answer_length], all_new_partial_answers_architecture[i:i + answer_length], answer_length, filters)
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# while i < answers_length:
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# self.create_grouped_answers()
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# i += 1
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i += answer_length
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# merged_results = []
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# for old_result in old_results:
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# for new_result in new_results:
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# merged_results.append(old_result + new_result)
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# return merged_results
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# children_queries_generator = self.generate_children_queries(all_query_indices, children)
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#
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# child_index = 0
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# child, child_queries, child_queries_metadata = next(children_queries_generator)
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# while child:
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# # obtain children results
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# new_partial_subtrees, new_completed_subtrees = child.get_subtrees(permanent_query_trees, child_queries, create_output_string)
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#
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# self.group_results(new_partial_subtrees, child_queries_metadata, all_query_indices,
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# partial_results_dict, partial_subtrees)
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#
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# for i in range(len(new_completed_subtrees)):
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# completed_subtrees[i].extend(new_completed_subtrees[i])
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# child, child_queries, child_queries_metadata = children_queries_generator.send(partial_results_dict)
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# child_index += 1
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return partial_subtrees_architectures, partial_subtrees, completed_subtrees
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def order_dependent_queries(self, active_permanent_query_trees, active_temporary_query_trees, partial_subtrees, partial_subtrees_architecture,
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create_output_string, merged_partial_subtrees, merged_partial_subtrees_architecture, i, i_child, filters):
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# string_output = ''
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if i < len(active_permanent_query_trees):
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if 'children' in active_permanent_query_trees[i]:
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if not filters['node_order'] or i_child < self.children_split:
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merged_partial_subtrees.append(
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self.create_output_left_children(partial_subtrees[i_child], [create_output_string(self)], filters))
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merged_partial_subtrees_architecture.append(
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self.create_output_left_children(partial_subtrees_architecture[i_child], [str([self.index])], filters))
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else:
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merged_partial_subtrees.append(
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self.create_output_right_children([create_output_string(self)], partial_subtrees[i_child], filters))
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merged_partial_subtrees_architecture.append(
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self.create_output_right_children([str([self.index])], partial_subtrees_architecture[i_child], filters))
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i_child += 1
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else:
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merged_partial_subtrees.append([create_output_string(self)])
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merged_partial_subtrees_architecture.append([str([self.index])])
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# merged_partial_subtrees.append([[create_output_string(self)]])
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else:
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if 'children' in active_temporary_query_trees[i - len(active_permanent_query_trees)]:
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if not filters['node_order'] or i_child < self.children_split:
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merged_partial_subtrees.append(
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self.create_output_left_children(partial_subtrees[i_child], [create_output_string(self)], filters))
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merged_partial_subtrees_architecture.append(
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self.create_output_left_children(partial_subtrees_architecture[i_child], [str([self.index])], filters))
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else:
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merged_partial_subtrees.append(
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self.create_output_right_children([create_output_string(self)], partial_subtrees[i_child], filters))
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merged_partial_subtrees_architecture.append(
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self.create_output_right_children([str([self.index])], partial_subtrees_architecture[i_child], filters))
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i_child += 1
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else:
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merged_partial_subtrees.append([create_output_string(self)])
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merged_partial_subtrees_architecture.append([str([self.index])])
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# merged_partial_subtrees.append([[create_output_string(self)]])
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return i_child
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def get_subtrees(self, permanent_query_trees, temporary_query_trees, create_output_string, filters):
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"""
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:param permanent_query_trees:
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:param temporary_query_trees:
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"""
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# list of all children queries grouped by parent queries
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all_query_indices = []
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active_permanent_query_trees = []
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for permanent_query_tree in permanent_query_trees:
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if self.fits_static_requirements(permanent_query_tree):
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active_permanent_query_trees.append(permanent_query_tree)
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if 'children' in permanent_query_tree:
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all_query_indices.append((permanent_query_tree['children'], True))
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# r_all_query_indices.append((permanent_query_tree['r_children'], True))
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active_temporary_query_trees = []
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successful_temporary_queries = []
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for i, temporary_query_tree in enumerate(temporary_query_trees):
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if self.fits_static_requirements(temporary_query_tree):
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active_temporary_query_trees.append(temporary_query_tree)
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successful_temporary_queries.append(i)
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# if 'l_children' in temporary_query_tree and 'r_children' in temporary_query_tree:
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if 'children' in temporary_query_tree:
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all_query_indices.append((temporary_query_tree['children'], False))
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partial_subtrees_architecture, partial_subtrees, completed_subtrees = self.get_all_query_indices(len(temporary_query_trees),
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len(permanent_query_trees),
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permanent_query_trees,
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all_query_indices, self.children,
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create_output_string, filters)
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merged_partial_subtrees = []
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merged_partial_subtrees_architecture = []
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i = 0
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i_child = 0
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# go over all permanent and temporary query trees
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while i < len(active_permanent_query_trees) + len(active_temporary_query_trees):
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# permanent query trees always have left and right child
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i_child = self.order_dependent_queries(active_permanent_query_trees, active_temporary_query_trees, partial_subtrees, partial_subtrees_architecture,
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create_output_string, merged_partial_subtrees, merged_partial_subtrees_architecture, i, i_child, filters)
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# if i < len(active_permanent_query_trees):
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# if ('l_children' in active_permanent_query_trees[i] and 'r_children' in active_permanent_query_trees[i]):
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# merged_partial_subtree = self.merge_results(l_partial_subtrees[i_left],
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# [[create_output_string(self)]])
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# merged_partial_subtrees.append(
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# self.merge_results(merged_partial_subtree, r_partial_subtrees[i_right]))
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# # merged_partial_subtrees.append(self.merge_results(l_partial_subtrees[i], [[create_output_string(self)]]))
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# i_left += 1
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# i_right += 1
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#
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# elif 'l_children' in active_permanent_query_trees[i]:
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# merged_partial_subtrees.append(
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# self.merge_results(l_partial_subtrees[i_left], [[create_output_string(self)]]))
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# i_left += 1
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#
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# elif 'r_children' in active_permanent_query_trees[i]:
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# merged_partial_subtrees.append(
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# self.merge_results([[create_output_string(self)]], r_partial_subtrees[i_right]))
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# i_right += 1
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# else:
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# merged_partial_subtrees.append([[create_output_string(self)]])
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# else:
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# if ('l_children' in active_temporary_query_trees[i - len(active_permanent_query_trees)] and 'r_children' in active_temporary_query_trees[i - len(active_permanent_query_trees)]):
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# merged_partial_subtree = self.merge_results(l_partial_subtrees[i_left], [[create_output_string(self)]])
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# merged_partial_subtrees.append(self.merge_results(merged_partial_subtree, r_partial_subtrees[i_right]))
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# # merged_partial_subtrees.append(self.merge_results(l_partial_subtrees[i], [[create_output_string(self)]]))
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# i_left += 1
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# i_right += 1
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#
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# elif 'l_children' in active_temporary_query_trees[i - len(active_permanent_query_trees)]:
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# merged_partial_subtrees.append(self.merge_results(l_partial_subtrees[i_left], [[create_output_string(self)]]))
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# i_left += 1
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#
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# elif 'r_children' in active_temporary_query_trees[i - len(active_permanent_query_trees)]:
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# merged_partial_subtrees.append(self.merge_results([[create_output_string(self)]], r_partial_subtrees[i_right]))
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# i_right += 1
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# else:
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# merged_partial_subtrees.append([[create_output_string(self)]])
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# # if r_partial_subtrees[i]:
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# # merged_partial_subtrees.append(self.merge_results(l_partial_subtrees[i], [[create_output_string(self)]]))
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i += 1
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# for i in range(len(permanent_query_trees)):
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# for i in range(max(len(completed_subtrees), len(r_completed_subtrees), len(active_permanent_query_trees))):
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for i in range(len(active_permanent_query_trees)):
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# erase first and last braclets when adding new query result
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add_subtree = [subtree[1:-1] for subtree in merged_partial_subtrees[i]]
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# if 0 < len(active_permanent_query_trees):
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completed_subtrees[i].extend(add_subtree)
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# completed_subtrees[i].extend(merged_partial_subtrees[i])
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# answers to valid queries
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subtrees_architecture = [[] for i in range(len(temporary_query_trees))]
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for inside_i, outside_i in enumerate(successful_temporary_queries):
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subtrees_architecture[outside_i] = merged_partial_subtrees_architecture[len(active_permanent_query_trees) + inside_i]
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# answers to valid queries
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subtrees = [[] for i in range(len(temporary_query_trees))]
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for inside_i, outside_i in enumerate(successful_temporary_queries):
|
|
subtrees[outside_i] = merged_partial_subtrees[
|
|
len(active_permanent_query_trees) + inside_i]
|
|
return subtrees_architecture, subtrees, completed_subtrees
|
|
# return merged_partial_subtrees_architecture[len(active_permanent_query_trees):], merged_partial_subtrees[len(active_permanent_query_trees):], completed_subtrees
|
|
|
|
@staticmethod
|
|
def merge_results(old_results, new_results):
|
|
merged_results = []
|
|
for old_result in old_results:
|
|
for new_result in new_results:
|
|
merged_results.append(old_result + new_result)
|
|
return merged_results
|
|
|
|
@staticmethod
|
|
def merge_answer(answer1, answer2, base_answer_i, answer_j):
|
|
merged_results = []
|
|
merged_indices = []
|
|
for answer1p_i, old_result in enumerate(answer1):
|
|
for answer2p_i, new_result in enumerate(answer2):
|
|
if answer1p_i != answer2p_i:
|
|
new_indices = [answer1p_i] + [answer2p_i]
|
|
sorted_indices = sorted(new_indices)
|
|
|
|
if sorted_indices in merged_indices:
|
|
test = merged_indices.index(sorted(new_indices))
|
|
# TODO add comparison answers with different indices if equal than ignore
|
|
merged_results.append(old_result + new_result)
|
|
merged_indices.append(new_indices)
|
|
return merged_results, merged_indices
|
|
|
|
@staticmethod
|
|
def create_output_left_children(left_children, new_results, filters):
|
|
merged_results = []
|
|
for child in left_children:
|
|
for new_result in new_results:
|
|
res = ''
|
|
if type(child) == str:
|
|
# res += '(' + child + ') < '
|
|
res += child + ' < '
|
|
else:
|
|
if filters['node_order']:
|
|
new_child = child
|
|
else:
|
|
new_child = sorted(child)
|
|
for el in new_child:
|
|
# res += '(' + el + ') < '
|
|
res += el + ' < '
|
|
merged_results.append('(' + res + new_result + ')')
|
|
return merged_results
|
|
|
|
@staticmethod
|
|
def create_output_right_children(new_results, right_children, filters):
|
|
merged_results = []
|
|
for child in right_children:
|
|
for new_result in new_results:
|
|
res = ''
|
|
if type(child) == str:
|
|
res += ' > ' + child
|
|
# res += ' > (' + child + ')'
|
|
else:
|
|
if filters['node_order']:
|
|
new_child = child
|
|
else:
|
|
new_child = sorted(child)
|
|
for el in new_child:
|
|
res += ' > ' + el
|
|
# res += ' > (' + el + ')'
|
|
merged_results.append('(' + new_result + res + ')')
|
|
# merged_results.append(new_result + ' > (' + child + ')')
|
|
return merged_results
|
|
|
|
@staticmethod
|
|
def create_answers(separated_answers, separated_answers_architecture, answer_length, filters):
|
|
# TODO
|
|
# node_order = False
|
|
partly_built_trees = [[None] * answer_length]
|
|
partly_built_trees_architecture = [[None] * answer_length]
|
|
partly_built_trees_architecture_indices = [[None] * answer_length]
|
|
built_trees = []
|
|
built_trees_architecture = []
|
|
built_trees_architecture_indices = []
|
|
# iterate over children first, so that new partly built trees are added only after all results of specific
|
|
# child are added
|
|
for child_i in range(len(separated_answers[0])):
|
|
new_partly_built_trees = []
|
|
new_partly_built_trees_architecture = []
|
|
new_partly_built_trees_architecture_indices = []
|
|
# iterate over answers parts
|
|
for answer_part_i in range(len(separated_answers)):
|
|
# necessary because some parts do not pass filters and are not added
|
|
# if child_i < len(separated_answers[answer_part_i]) and separated_answers[answer_part_i][child_i]:
|
|
if separated_answers[answer_part_i][child_i]:
|
|
for tree_part_i, tree_part in enumerate(partly_built_trees):
|
|
# if tree_part[answer_part_i] equals None add new element in its place
|
|
if not tree_part[answer_part_i]:
|
|
new_tree_part = copy(tree_part)
|
|
new_tree_part_architecture = copy(partly_built_trees_architecture[tree_part_i])
|
|
new_tree_part_architecture_indices = copy(partly_built_trees_architecture_indices[tree_part_i])
|
|
new_tree_part[answer_part_i] = separated_answers[answer_part_i][child_i][0]
|
|
new_tree_part_architecture[answer_part_i] = separated_answers_architecture[answer_part_i][child_i][0]
|
|
new_tree_part_architecture_indices[answer_part_i] = child_i
|
|
completed_tree_part = True
|
|
for val_i, val in enumerate(new_tree_part):
|
|
if not val:
|
|
completed_tree_part = False
|
|
if completed_tree_part:
|
|
built_trees.append(new_tree_part)
|
|
built_trees_architecture.append(new_tree_part_architecture)
|
|
built_trees_architecture_indices.append(new_tree_part_architecture_indices)
|
|
else:
|
|
new_partly_built_trees.append(new_tree_part)
|
|
new_partly_built_trees_architecture.append(new_tree_part_architecture)
|
|
new_partly_built_trees_architecture_indices.append(new_tree_part_architecture_indices)
|
|
|
|
partly_built_trees.extend(new_partly_built_trees)
|
|
partly_built_trees_architecture.extend(new_partly_built_trees_architecture)
|
|
partly_built_trees_architecture_indices.extend(new_partly_built_trees_architecture_indices)
|
|
|
|
l_ordered_built_trees_architecture, l_ordered_built_trees, r_ordered_built_trees_architecture, r_ordered_built_trees, unique_trees_architecture = [], [], [], [], []
|
|
|
|
if built_trees:
|
|
# sort 3 arrays by architecture indices
|
|
temp_trees_architecture_indice, temp_trees, temp_trees_architectures = (list(t) for t in zip(
|
|
*sorted(zip(built_trees_architecture_indices, built_trees, built_trees_architecture))))
|
|
|
|
# order outputs and erase duplicates
|
|
# for tree, tree_architecture, tree_architecture_indice in zip(built_trees, built_trees_architecture, built_trees_architecture_indices):
|
|
for tree, tree_architecture, tree_architecture_indice in zip(temp_trees, temp_trees_architectures, temp_trees_architecture_indice):
|
|
new_tree_architecture_indice, new_tree, new_tree_architecture = (list(t) for t in zip(*sorted(zip(tree_architecture_indice, tree, tree_architecture))))
|
|
# TODO check if inside new_tree_architecture in ordered_built_trees_architecture and if not append!
|
|
is_unique = True
|
|
for unique_tree in unique_trees_architecture:
|
|
already_in = True
|
|
for part_i in range(len(unique_tree)):
|
|
if unique_tree[part_i] != new_tree_architecture[part_i]:
|
|
already_in = False
|
|
break
|
|
if already_in:
|
|
is_unique = False
|
|
break
|
|
|
|
if is_unique:
|
|
unique_trees_architecture.append(new_tree_architecture)
|
|
# if not filters['node_order']:
|
|
l_ordered_built_trees_architecture.append(new_tree_architecture)
|
|
l_ordered_built_trees.append(new_tree)
|
|
# TODO NODE ORDER = FALSE
|
|
# else:
|
|
#
|
|
# ordered_built_trees_architecture.append(tree_architecture)
|
|
# ordered_built_trees.append(tree)
|
|
# print("test")
|
|
# for answer1_i, answer1 in enumerate(separated_answers):
|
|
# for answer2_i, answer2 in enumerate(separated_answers):
|
|
# if answer1_i != answer2_i:
|
|
# res, res_i = self.merge_answer(answer1, answer2, answer1_i, answer2_i)
|
|
# print('aaa')
|
|
#
|
|
# pass
|
|
return l_ordered_built_trees, l_ordered_built_trees_architecture
|
|
|
|
|
|
def create_output_string_form(tree):
|
|
return tree.form.get_value()
|
|
|
|
def create_output_string_deprel(tree):
|
|
return tree.deprel.get_value()
|
|
|
|
def create_output_string_lemma(tree):
|
|
return tree.lemma.get_value()
|
|
|
|
def create_output_string_upos(tree):
|
|
return tree.upos.get_value()
|
|
|
|
def create_output_string_xpos(tree):
|
|
return tree.xpos.get_value()
|