voc_words = get_vocabulary(inputs, 0.0) # collect vocabulary of input lemmas
voc_senses_BN = get_vocab_senses(bnIds, 0.0) # collect vocabulary of FG senses
voc_joint_BN = voc_words + voc_senses_BN # create joint voc.
voc_senses_WND = get_vocab_senses(wndIds,
0.0) # collect vocabulary of CG-WND senses
voc_joint_WND = voc_words + voc_senses_WND # create joint voc.
voc_senses_LEX = get_vocab_senses(lexIds,
0.0) # collect vocabulary of CG-LEX senses
voc_joint_LEX = voc_words + voc_senses_LEX # create joint voc.
inputs, max_lengths = pre_ELMO(
inputs,
MAX_LENGTH) # prepare the input for matching ELMo embedding requirements
labels_BN = indexing(
labels_BN, voc_joint_BN,
MAX_LENGTH) # prepare the BN labels for matching network requirements
labels_BN = np.expand_dims(np.copy(labels_BN), axis=-1)
labels_WND = indexing(
labels_WND, voc_joint_WND,
MAX_LENGTH) # prepare the WND labels for matching network requirements
labels_WND = np.expand_dims(np.copy(labels_WND), axis=-1)
labels_LEX = indexing(
labels_LEX, voc_joint_LEX,
MAX_LENGTH) # prepare the LEX labels for matching network requirements
def predict_lexicographer(input_path: str, output_path: str,
resources_path: str) -> None:
"""
DO NOT MODIFY THE SIGNATURE!
This is the skeleton of the prediction function.
The predict function will build your model, load the weights from the checkpoint and write a new file (output_path)
with your predictions in the "<id> <lexicographerId>" format (e.g. "d000.s000.t000 noun.animal").
The resources folder should contain everything you need to make the predictions. It is the "resources" folder in your submission.
N.B. DO NOT HARD CODE PATHS IN HERE. Use resource_path instead, otherwise we will not be able to run the code.
If you don't know what HARD CODING means see: https://en.wikipedia.org/wiki/Hard_coding
:param input_path: the path of the input file to predict in the same format as Raganato's framework (XML files you downloaded).
:param output_path: the path of the output file (where you save your predictions)
:param resources_path: the path of the resources folder containing your model and stuff you might need.
:return: None
"""
batch_size = 32
max_len = 50
out_file = open(output_path, 'w', encoding='utf-8')
inputs, pos, flags, ids = blind_parsing(input_path) # parsing xml
with open(resources_path + '/vocabulary', 'rb') as f:
vocFG = pickle.load(f)
with open(resources_path + '/vocabularyWND', 'rb') as f:
vocWND = pickle.load(f)
with open(resources_path + '/vocabularyLEX', 'rb') as f:
vocLEX = pickle.load(f)
wn2bn_dict = get_dictionary(resources_path + '/babelnet2wordnet.tsv', 1)
bn2lex_dict = get_dictionary(resources_path + '/babelnet2lexnames.tsv', 0)
model = MultitaskBiLSTM((max_len, ), len(vocFG), len(vocWND), len(vocLEX),
HIDDEN_SIZE, DROPOUT, DROPOUT_REC)
model.load_weights(resources_path + '/mod082_weights.h5')
inputs = crop(inputs, max_len)
pos = crop(pos, max_len)
flags = crop(flags, max_len)
ids = crop(ids, max_len)
pos = ext(pos, max_len, batch_size, 'pos')
flags = ext(flags, max_len, batch_size, 'flags')
ids = ext(ids, max_len, batch_size, 'ids')
inputs = ext(inputs, max_len, batch_size, 'inputs')
inputs, _ = pre_ELMO(inputs, max_len)
predictions = model.predict(inputs, batch_size=batch_size, verbose=True)[2]
for r, sentence in enumerate(flags): # for each sentence
for c, word in enumerate(sentence): # for each word
if word: # flag = True, that word must be disambiguated
pox_synsets = get_synsetsIds(inputs[r][c], pos[r][c],
wn2bn_dict)
pox_synsets = convert_bn2lex(pox_synsets, bn2lex_dict)
pox_synsets = restrict_index_synsets(pox_synsets, vocLEX)
if len(pox_synsets) == 0:
best = get_MFS(inputs[r][c], wn2bn_dict)
best = convert_bn2lex([best], bn2lex_dict)[0]
else:
best = get_best(predictions[r][c], pox_synsets, vocLEX)
out_file.write(ids[r][c] + ' ' + best + '\n')
out_file.close()
pass
def predict_babelnet_mod096_MODIFIED(input_path: str, output_path: str,
resources_path: str) -> None:
batch_size = 32
max_len = 50
out_file = open(output_path, 'w', encoding='utf-8')
inputs, pos, flags, ids = blind_parsing(input_path) # parsing xml
with open(resources_path + '/OMSTI_voc_LEX', 'rb') as f:
voc_LEX = pickle.load(f)
with open(resources_path + '/OMSTI_voc_BN', 'rb') as f:
voc_BN = pickle.load(f)
with open(resources_path + '/OMSTI_voc_WND', 'rb') as f:
voc_WND = pickle.load(f)
wn2bn_dict = get_dictionary(resources_path + '/babelnet2wordnet.tsv', 1)
bn2lex_dict = get_dictionary(resources_path + '/babelnet2lexnames.tsv', 0)
bn2wnd_dict = get_dictionary(resources_path + '/babelnet2wndomains.tsv', 0)
model = MultitaskBiLSTM((max_len, ), len(voc_BN), len(voc_WND),
len(voc_LEX), HIDDEN_SIZE, DROPOUT, DROPOUT_REC)
model.load_weights(resources_path + '/mod_OMSTI_082_weights.h5')
inputs = crop(inputs, max_len)
pos = crop(pos, max_len)
flags = crop(flags, max_len)
ids = crop(ids, max_len)
inputs = ext(inputs, max_len, batch_size, 'inputs')
pos = ext(pos, max_len, batch_size, 'pos')
flags = ext(flags, max_len, batch_size, 'flags')
ids = ext(ids, max_len, batch_size, 'ids')
inputs, _ = pre_ELMO(inputs, max_len)
pred_BN, pred_WND, pred_LEX = model.predict(inputs,
batch_size=batch_size,
verbose=True)
for r, sentence in enumerate(flags): # for each sentence
for c, word in enumerate(sentence): # for each word
if word: # flag = True, that word must be disambiguated
pox_synsets = get_synsetsIds(inputs[r][c], pos[r][c],
wn2bn_dict)
pox_LEX = convert_bn2lex(pox_synsets, bn2lex_dict)
pox_LEX = restrict_index_synsets(pox_LEX, voc_LEX)
if len(pox_LEX) == 0:
bestLEX = get_MFS(inputs[r][c], wn2bn_dict)
bestLEX = convert_bn2lex([bestLEX], bn2lex_dict)[0]
else:
bestLEX = get_best(pred_LEX[r][c], pox_LEX,
voc_LEX) # best lex cathegory
pox_WND = convert_bn2wnd(pox_synsets, bn2wnd_dict)
pox_WND = restrict_index_synsets(pox_WND, voc_WND)
if len(pox_WND) == 0:
bestWND = get_MFS(inputs[r][c], wn2bn_dict)
bestWND = convert_bn2wnd([bestWND], bn2wnd_dict)[0]
else:
bestWND = get_best(pred_WND[r][c], pox_WND,
voc_WND) # best lex cathegory
pox_synsets = filter_with_LEX(
pox_synsets, bestLEX,
bn2lex_dict) # pox synsets restricted with lex
pox_synsets = filter_with_WND(pox_synsets, bestWND,
bn2wnd_dict)
pox_synsets = restrict_index_synsets(pox_synsets, voc_BN)
if len(pox_synsets) == 0:
best = get_MFS(inputs[r][c], wn2bn_dict)
else:
best = get_best(pred_BN[r][c], pox_synsets, voc_BN)
# write best on external sheet
out_file.write(ids[r][c] + ' ' + best + '\n')
out_file.close()
pass
def predict_babelnet(input_path: str, output_path: str,
resources_path: str) -> None:
"""
DO NOT MODIFY THE SIGNATURE!
This is the skeleton of the prediction function.
The predict function will build your model, load the weights from the checkpoint and write a new file (output_path)
with your predictions in the "<id> <BABELSynset>" format (e.g. "d000.s000.t000 bn:01234567n").
The resources folder should contain everything you need to make the predictions. It is the "resources" folder in your submission.
N.B. DO NOT HARD CODE PATHS IN HERE. Use resource_path instead, otherwise we will not be able to run the code.
If you don't know what HARD CODING means see: https://en.wikipedia.org/wiki/Hard_coding
:param input_path: the path of the input file to predict in the same format as Raganato's framework (XML files you downloaded).
:param output_path: the path of the output file (where you save your predictions)
:param resources_path: the path of the resources folder containing your model and stuff you might need.
:return: None
"""
batch_size = 32
max_len = 50
out_file = open(output_path, 'w', encoding='utf-8')
inputs, pos, flags, ids = blind_parsing(
input_path
) # parsing xml (inputs: list of lists of lemmas, pos: list of lists of POS, flags:
# list of lists of boolean (True:to disamb, False otherwise) and ids: list of lists of ids)
with open(resources_path + '/OMSTI_voc_LEX',
'rb') as f: # retrieving vocabularies
voc_LEX = pickle.load(f)
with open(resources_path + '/OMSTI_voc_BN', 'rb') as f:
voc_BN = pickle.load(f)
with open(resources_path + '/OMSTI_voc_WND', 'rb') as f:
voc_WND = pickle.load(f)
wn2bn_dict = get_dictionary(resources_path + '/babelnet2wordnet.tsv',
1) # retrieving mappings
bn2lex_dict = get_dictionary(resources_path + '/babelnet2lexnames.tsv', 0)
bn2wnd_dict = get_dictionary(resources_path + '/babelnet2wndomains.tsv', 0)
model = MultitaskBiLSTM((max_len, ), len(voc_BN), len(voc_WND),
len(voc_LEX), HIDDEN_SIZE, DROPOUT,
DROPOUT_REC) # initialize the model
model.load_weights(resources_path +
'/mod_OMSTI_082_weights.h5') # load weights
# Shaping the inputs, pos, flags and ids to match ELMo and network requirements
inputs = crop(inputs, max_len)
pos = crop(pos, max_len)
flags = crop(flags, max_len)
ids = crop(ids, max_len)
inputs = ext(inputs, max_len, batch_size, 'inputs')
pos = ext(pos, max_len, batch_size, 'pos')
flags = ext(flags, max_len, batch_size, 'flags')
ids = ext(ids, max_len, batch_size, 'ids')
inputs, _ = pre_ELMO(inputs, max_len)
pred_BN, pred_WND, pred_LEX = model.predict(inputs,
batch_size=batch_size,
verbose=True) # predict
for r, sentence in enumerate(flags): # for each sentence
for c, word in enumerate(sentence): # for each word
if word: # flag = True, that word must be disambiguated
pox_synsets = get_synsetsIds(
inputs[r][c], pos[r][c],
wn2bn_dict) #retrieve candidate synsets
pox_LEX = convert_bn2lex(pox_synsets, bn2lex_dict)
pox_LEX = restrict_index_synsets(
pox_LEX, voc_LEX
) # restrict pox synsets to only those belonging to the vocabulary
if len(pox_LEX) == 0: # if non is present
bestLEX = get_MFS(inputs[r][c],
wn2bn_dict) # backoff strategy
bestLEX = convert_bn2lex(
[bestLEX],
bn2lex_dict)[0] # get LEX category of bakeoff strategy
else:
bestLEX = get_best(pred_LEX[r][c], pox_LEX,
voc_LEX) # best LEX cathegory
pox_WND = convert_bn2wnd(pox_synsets, bn2wnd_dict)
pox_WND = restrict_index_synsets(
pox_WND, voc_WND
) # restrict pox synsets to only those belonging to the vocabulary
if len(pox_WND) == 0:
bestWND = get_MFS(inputs[r][c],
wn2bn_dict) # backoff strategy
bestWND = convert_bn2wnd(
[bestWND],
bn2wnd_dict)[0] # get WND category of bakeoff strategy
else:
bestWND = get_best(pred_WND[r][c], pox_WND,
voc_WND) # best WND cathegory
pox_synsets = filter_with_LEX(
pox_synsets, bestLEX,
bn2lex_dict) # pox synsets restricted with LEX
pox_synsets = filter_with_WND(
pox_synsets, bestWND,
bn2wnd_dict) # pox synsets restricted with WND
pox_synsets = restrict_index_synsets(pox_synsets, voc_BN)
if len(pox_synsets) == 0:
best = get_MFS(inputs[r][c],
wn2bn_dict) # backoff strategy
else:
best = get_best(pred_BN[r][c], pox_synsets,
voc_BN) # best synset like BabelNet id
out_file.write(
ids[r][c] + ' ' + best + '\n'
) # write on the external file matching the format required
out_file.close()
pass
def predict_babelnet_mod095(input_path: str, output_path: str,
resources_path: str) -> None:
batch_size = 32
max_len = 50
out_file = open(output_path, 'w', encoding='utf-8')
inputs, pos, flags, ids = blind_parsing(input_path) # parsing xml
with open(resources_path + '/vocabularyLEX', 'rb') as f:
voc_LEX = pickle.load(f)
with open(resources_path + '/vocabulary', 'rb') as f:
voc_BN = pickle.load(f)
with open(resources_path + '/vocabularyWND', 'rb') as f:
voc_WND = pickle.load(f)
wn2bn_dict = get_dictionary(resources_path + '/babelnet2wordnet.tsv', 1)
bn2lex_dict = get_dictionary(resources_path + '/babelnet2lexnames.tsv', 0)
bn2wnd_dict = get_dictionary(resources_path + '/babelnet2wndomains.tsv', 0)
model_in2lex = AttentionBiLSTM((max_len, ), len(voc_LEX), EMB_SIZE,
HIDDEN_SIZE, DROPOUT, DROPOUT_REC)
model_in2lex.load_weights(resources_path + '/mod06_LEX_weights.h5')
inputs = crop(inputs, max_len)
flags = crop(flags, max_len)
ids = crop(ids, max_len)
pos = crop(pos, max_len)
flags = ext(flags, max_len, batch_size, 'flags')
ids = ext(ids, max_len, batch_size, 'ids')
pos = ext(pos, max_len, batch_size, 'pos')
inputs = ext(inputs, max_len, batch_size, 'inputs')
flags = pad_sequences(flags,
maxlen=max_len,
dtype='bool',
padding='post',
value=False)
inputs, _ = pre_ELMO(inputs, max_len)
preds_LEX = model_in2lex.predict(inputs,
batch_size=batch_size,
verbose=True)
inputs_LEX = []
for r, sentence in enumerate(flags): # for each sentence
inputs_LEX_part = []
for c, word in enumerate(sentence): # for each word
if word: # flag = True, that word must be disambiguated
pox_synsets = get_synsetsIds(inputs[r][c], pos[r][c],
wn2bn_dict)
pox_LEX = convert_bn2lex(pox_synsets, bn2lex_dict)
pox_LEX = restrict_index_synsets(pox_LEX, voc_LEX)
if len(pox_LEX) == 0:
bestLEX = get_MFS(inputs[r][c], wn2bn_dict)
bestLEX = convert_bn2lex([bestLEX], bn2lex_dict)[0]
else:
bestLEX = get_best(preds_LEX[r][c], pox_LEX,
voc_LEX) # best lex cathegory
bestLEX = voc_LEX.index(bestLEX)
else:
bestLEX = np.argmax(preds_LEX[r][c])
inputs_LEX_part.append(bestLEX)
inputs_LEX.append(inputs_LEX_part)
inputs_LEX = np.asarray(inputs_LEX)
model_inLex2wn = Model095A([(max_len, ), inputs_LEX.shape[1:2]],
len(voc_LEX), len(voc_WND), EMB_SIZE,
HIDDEN_SIZE, DROPOUT, DROPOUT_REC)
model_inLex2wn.load_weights(resources_path + '/mod095A_weights.h5')
preds_WND = model_inLex2wn.predict([inputs, inputs_LEX],
batch_size=batch_size,
verbose=True)
inputs_WND = []
for r, sentence in enumerate(flags): # for each sentence
inputs_WND_part = []
for c, word in enumerate(sentence): # for each word
if word: # flag = True, that word must be disambiguated
pox_synsets = get_synsetsIds(inputs[r][c], pos[r][c],
wn2bn_dict)
pox_WND = convert_bn2wnd(pox_synsets, bn2wnd_dict)
pox_WND = restrict_index_synsets(pox_WND, voc_WND)
if len(pox_WND) == 0:
bestWND = get_MFS(inputs[r][c], wn2bn_dict)
bestWND = convert_bn2lex([bestWND], bn2wnd_dict)[0]
else:
bestWND = get_best(preds_WND[r][c], pox_WND,
voc_WND) # best lex cathegory
bestWND = voc_WND.index(bestWND)
else:
bestWND = np.argmax(preds_WND[r][c])
inputs_WND_part.append(bestWND)
inputs_WND.append(inputs_WND_part)
inputs_WND = np.asarray(inputs_WND)
model_inWnd2bn = Model095B([(max_len, ), inputs_LEX.shape[1:2]],
len(voc_WND), len(voc_BN), EMB_SIZE,
HIDDEN_SIZE, DROPOUT, DROPOUT_REC)
model_inWnd2bn.load_weights(resources_path + '/mod095B_weights.h5')
predictions = model_inWnd2bn.predict([inputs, inputs_WND],
batch_size=batch_size,
verbose=True)
for r, sentence in enumerate(flags): # for each sentence
for c, word in enumerate(sentence): # for each word
if word: # flag = True, that word must be disambiguated
pox_synsets = get_synsetsIds(inputs[r][c], pos[r][c],
wn2bn_dict)
pox_synsets = restrict_index_synsets(pox_synsets, voc_BN)
if len(pox_synsets) == 0:
best = get_MFS(inputs[r][c], wn2bn_dict)
else:
best = get_best(predictions[r][c], pox_synsets, voc_BN)
# write best on external sheet
out_file.write(ids[r][c] + ' ' + best + '\n')
out_file.close()
pass