def decode(self, dec_lstm, vectors, output_batch): # output = [EOS] + list(output) + [EOS] # output = [char2int[c] for c in output] w = dy.parameter(decoder_w) b = dy.parameter(decoder_b) w1 = dy.parameter(attention_w1) input_mat = dy.concatenate_cols(vectors) input_len = len(vectors) w1dt = w1 * input_mat curr_bsize = len(output_batch) #n_batch_start = [1] * curr_bsize #last_output_embeddings = dy.lookup_batch(output_lookup, n_batch_start) s = dec_lstm.initial_state() c_t_previous = dy.vecInput(STATE_SIZE * 2) loss = [] output_batch, masks = self.create_sentence_batch(output_batch) for i, (word_batch, mask_word) in enumerate(zip(output_batch[1:], masks[1:]), start=1): last_output_embeddings = dy.lookup_batch(output_lookup, output_batch[i - 1]) vector = dy.concatenate([last_output_embeddings, c_t_previous]) s = s.add_input(vector) h_t = s.output() c_t, alpha_t = self.attend(input_mat, s, w1dt, input_len, curr_bsize) h_c_concat = dy.concatenate([h_t, c_t]) out_vector = dy.affine_transform([b, w, h_c_concat]) if DROPOUT > 0.0: out_vector = dy.dropout(out_vector, DROPOUT) loss_current = dy.pickneglogsoftmax_batch(out_vector, output_batch[i]) if 0 in mask_word: mask_vals = dy.inputVector(mask_word) mask_vals = dy.reshape(mask_vals, (1, ), curr_bsize) loss_current = loss_current * mask_vals loss.append(loss_current) c_t_previous = c_t loss = dy.esum(loss) loss = dy.sum_batches(loss) / curr_bsize #perplexity = loss.value() * curr_bsize / float(sum([x.count(1) for x in masks[1:]])) return loss
def decode_batch(dec_lstm, input_encodings, output_sentences): #print "in decode batch" w = dy.parameter(decoder_w) b = dy.parameter(decoder_b) w1 = dy.parameter(attention_w1) output_words, masks = sentences_to_batch(output_sentences) decoder_target_input = zip(output_words[1:], masks[1:]) batch_size = len(output_sentences) input_length = len(input_encodings) input_mat = dy.concatenate_cols(input_encodings) #print "Computing w1dt" w1dt = w1 * input_mat s = dec_lstm.initial_state() c_t_minus_1 = dy.vecInput(state_size * 2) loss = [] for t, (words_t, mask_t) in enumerate(decoder_target_input, start = 1): last_output_embeddings = dy.lookup_batch(output_lookup, output_words[t-1]) vector = dy.concatenate([last_output_embeddings, c_t_minus_1]) s = s.add_input(vector) h_t = s.output() #print "Calling attend" c_t = attend_batch(input_mat, s, w1dt, batch_size, input_length) predicted = dy.affine_transform([b, w, dy.concatenate([h_t, c_t])]) if(dropout > 0.): predicted = dy.dropout(predicted, dropout) cur_loss = dy.pickneglogsoftmax_batch(predicted, words_t) c_t_minus_1 = c_t #Mask the loss in case mask == 0 if 0 in mask_t: mask = dy.inputVector(mask_t) mask = dy.reshape(mask, (1, ), batch_size) cur_loss = cur_loss * mask loss.append(cur_loss) #Get the average batch loss loss = dy.esum(loss) loss = dy.sum_batches(loss) / batch_size return loss
def myDecode(self, dec_lstm, h_encodings, target_sents): w = dy.parameter(decoder_w) b = dy.parameter(decoder_b) w1 = dy.parameter(attention_w1) dec_wrds, dec_mask = self.pad_zero(target_sents) curr_bsize = len(target_sents) h_len = len(h_encodings) H_source = dy.concatenate_cols(h_encodings) s = dec_lstm.initial_state() ctx_t0 = dy.vecInput(hidden_size * 2) w1dt = w1 * H_source loss = [] #print curr_bsize for sent in range(1, len(dec_wrds)): last_output_embeddings = dy.lookup_batch(output_lookup, dec_wrds[sent-1]) x = dy.concatenate([ctx_t0, last_output_embeddings]) s = s.add_input(x) h_t = s.output() ctx_t, alpha_t = self.attend(H_source, s, w1dt, h_len, curr_bsize) output_vector = w * dy.concatenate([h_t, ctx_t]) + b #probs = dy.softmax(output_vector) ctx_t0 = ctx_t if dropout_config: output_vector = dy.dropout(output_vector, dropout_val) temp_loss = dy.pickneglogsoftmax_batch(output_vector, dec_wrds[sent]) if 0 in dec_mask[sent]: mask_expr = dy.inputVector(dec_mask[sent]) mask_expr = dy.reshape(mask_expr, (1, ), curr_bsize) temp_loss = temp_loss * mask_expr loss.append(temp_loss) loss = dy.esum(loss) loss = dy.sum_batches(loss) / batch_size return loss
def calc_lm_loss(sents): dy.renew_cg() # parameters -> expressions W_exp = dy.parameter(W_sm) b_exp = dy.parameter(b_sm) # initialize the RNN f_init = RNN.initial_state() # get the wids and masks for each step tot_words = 0 wids = [] masks = [] for i in range(len(sents[0])): wids.append([(vw.w2i[sent[i]] if len(sent) > i else STOP) for sent in sents]) mask = [(1 if len(sent) > i else 0) for sent in sents] masks.append(mask) tot_words += sum(mask) # start the rnn by inputting "<start>" init_ids = [START] * len(sents) s = f_init.add_input(dy.lookup_batch(WORDS_LOOKUP, init_ids)) # feed word vectors into the RNN and predict the next word losses = [] for wid, mask in zip(wids, masks): # calculate the softmax and loss score = W_exp * s.output() + b_exp loss = dy.pickneglogsoftmax_batch(score, wid) # mask the loss if at least one sentence is shorter if mask[-1] != 1: mask_expr = dy.inputVector(mask) mask_expr = dy.reshape(mask_expr, (1,), MB_SIZE) loss = loss * mask_expr losses.append(loss) # update the state of the RNN wemb = dy.lookup_batch(WORDS_LOOKUP, wid) s = s.add_input(wemb) return dy.sum_batches(dy.esum(losses)), tot_words
def decode_batch(dec_lstm, input_encodings, output_sentences): #print "in decode batch" w = dy.parameter(decoder_w) b = dy.parameter(decoder_b) w1 = dy.parameter(attention_w1) output_words, masks = sentences_to_batch(output_sentences) #decoder_target_input = zip(output_words[1:], masks[1:]) batch_size = len(output_sentences) input_length = len(input_encodings) input_mat = dy.concatenate_cols(input_encodings) #print "Computing w1dt" w1dt = w1 * input_mat s = dec_lstm.initial_state() c_t_minus_1 = dy.vecInput(state_size * 2) loss = [] for t in range(1, len(output_words)): last_output_embeddings = dy.lookup_batch(output_lookup, output_words[t-1]) vector = dy.concatenate([c_t_minus_1, last_output_embeddings]) s = s.add_input(vector) h_t = s.output() #print "Calling attend" c_t = attend_batch(input_mat, s, w1dt, batch_size, input_length) predicted = w * dy.concatenate([h_t, c_t]) + b if(dropout > 0.): predicted = dy.dropout(predicted, dropout) cur_loss = dy.pickneglogsoftmax_batch(predicted, output_words[t]) c_t_minus_1 = c_t #Mask the loss in case mask == 0 if 0 in masks[t]: mask = dy.inputVector(masks[t]) mask = dy.reshape(mask, (1, ), batch_size) cur_loss = cur_loss * mask loss.append(cur_loss)
def build_batch_sentences_graph(isents, builders): #NEXT STAGE - remove sentences that are not the same length from batch, and remove all mask stuff renew_cg() f_init, b_init = [b.initial_state() for b in builders] W = parameter(W_sm) b = parameter(b_sm) #Train first forward direction LSTM #Init forward aux variables f_tot_words = 0 f_wids_list = [] f_masks = [] #Prepare the batch. Mask shorter sentences for i in range(len(isents[0])): f_wids_list.append([(vw.w2i[sent[i]] if len(sent) > i else STOP) for sent in isents]) mask = [(1 if len(sent) > i else 0) for sent in isents] f_masks.append(mask) f_tot_words += sum(mask) #Feed the batched words into forward lstm f_outputs = [] state = f_init for wids in f_wids_list: #wids is a list of i-th word in each sentence across the batch wembs = dy.lookup_batch(WORDS_LOOKUP, wids) state = state.add_input(wembs) f_outputs.append(state.output()) #get output batch #Train backward direction of lstm b_tot_words = 0 b_wids_list = [] b_masks = [] # Prepare the batch. Mask shorter sentences for i in range(len(isents[0])): b_wids_list.append([(vw.w2i[sent[::-1][i]] if len(sent) > i else START) for sent in isents]) mask = [(1 if len(sent) > i else 0) for sent in isents] b_masks.append(mask) b_tot_words += sum(mask) # Feed the batched words into backward lstm b_outputs = [] state = b_init for wids in b_wids_list: # wids is a list of i-th word in each sentence across the batch wembs = dy.lookup_batch(WORDS_LOOKUP, wids) state = state.add_input(wembs) b_outputs.append(state.output()) # get output batch #Compute loss via batch softmax errs = [] for i in range(len(isents[0]) - 3): y = concatenate([f_outputs[i], b_outputs[::-1][i + 2]]) r = b + (W * y) err = pickneglogsoftmax_batch(r, f_wids_list[i + 1]) #print "FMASK", f_masks if f_masks[i][-1] != 1 or b_masks[::-1][i + 2][-1] != 1: complete_mask = f_masks + b_masks # print "COMPLETE", complete_mask mask_expr = dy.inputVector(complete_mask) mask_expr = dy.reshape(mask_expr, (1, ), MB_SIZE) err = err * mask_expr errs.append(err) losses = sum_batches(esum(errs)) return losses
def loss(self, observation, target_rep): return dy.squared_distance(observation, dy.inputVector(target_rep))
def build_batch_sentences_graph(isents, builders): #NEXT STAGE - remove sentences that are not the same length from batch, and remove all mask stuff renew_cg() f_init, b_init = [b.initial_state() for b in builders] W = parameter(W_sm) b = parameter(b_sm) #Train first forward direction LSTM #Init forward aux variables f_tot_words = 0 f_wids_list = [] f_masks = [] #Prepare the batch. Mask shorter sentences for i in range(len(isents[0])): f_wids_list.append([(vw.w2i[sent[i]] if len(sent) > i else STOP) for sent in isents]) mask = [(1 if len(sent) > i else 0) for sent in isents] f_masks.append(mask) f_tot_words += sum(mask) #Feed the batched words into forward lstm f_outputs = [] state = f_init for wids in f_wids_list: #wids is a list of i-th word in each sentence across the batch wembs = dy.lookup_batch(WORDS_LOOKUP, wids) state = state.add_input(wembs) f_outputs.append(state.output()) #get output batch #Train backward direction of lstm b_tot_words = 0 b_wids_list = [] b_masks = [] # Prepare the batch. Mask shorter sentences for i in range(len(isents[0])): b_wids_list.append([(vw.w2i[sent[::-1][i]] if len(sent) > i else START) for sent in isents]) mask = [(1 if len(sent) > i else 0) for sent in isents] b_masks.append(mask) b_tot_words += sum(mask) # Feed the batched words into backward lstm b_outputs = [] state = b_init for wids in b_wids_list: # wids is a list of i-th word in each sentence across the batch wembs = dy.lookup_batch(WORDS_LOOKUP, wids) state = state.add_input(wembs) b_outputs.append(state.output()) # get output batch #Compute loss via batch softmax errs = [] for i in range(len(isents[0])-3): y = concatenate([f_outputs[i], b_outputs[::-1][i+2]]) r = b + (W * y) err = pickneglogsoftmax_batch(r, f_wids_list[i+1]) #print "FMASK", f_masks if f_masks[i][-1] != 1 or b_masks[::-1][i+2][-1] != 1: complete_mask = f_masks + b_masks # print "COMPLETE", complete_mask mask_expr = dy.inputVector(complete_mask) mask_expr = dy.reshape(mask_expr, (1,), MB_SIZE) err = err * mask_expr errs.append(err) losses = sum_batches(esum(errs)) return losses
def __step_batch(self, batch): dy.renew_cg() W_y = dy.parameter(self.W_y) b_y = dy.parameter(self.b_y) F = len(batch[0][0]) num_words = F * len(batch) src_batch = [x[0] for x in batch] tgt_batch = [x[1] for x in batch] src_rev_batch = [list(reversed(x)) for x in src_batch] # batch = [ [a1,a2,a3,a4,a5], [b1,b2,b3,b4,b5], [c1,c2,c3,c4] ..] # transpose the batch into # src_cws: [[a1,b1,c1,..], [a2,b2,c2,..], .. [a5,b5,</S>]] src_cws = map(list, zip(*src_batch)) # transpose src_rev_cws = map(list, zip(*src_rev_batch)) # Bidirectional representations l2r_state = self.l2r_builder.initial_state() r2l_state = self.r2l_builder.initial_state() l2r_contexts = [] r2l_contexts = [] for (cw_l2r_list, cw_r2l_list) in zip(src_cws, src_rev_cws): l2r_state = l2r_state.add_input( dy.lookup_batch(self.src_lookup, [ self.src_token_to_id.get(cw_l2r, 0) for cw_l2r in cw_l2r_list ])) r2l_state = r2l_state.add_input( dy.lookup_batch(self.src_lookup, [ self.src_token_to_id.get(cw_r2l, 0) for cw_r2l in cw_r2l_list ])) l2r_contexts.append( l2r_state.output()) #[<S>, x_1, x_2, ..., </S>] r2l_contexts.append( r2l_state.output()) #[</S> x_n, x_{n-1}, ... <S>] r2l_contexts.reverse() #[<S>, x_1, x_2, ..., </S>] # Combine the left and right representations for every word h_fs = [] for (l2r_i, r2l_i) in zip(l2r_contexts, r2l_contexts): h_fs.append(dy.concatenate([l2r_i, r2l_i])) h_fs_matrix = dy.concatenate_cols(h_fs) losses = [] # Decoder # batch = [ [a1,a2,a3,a4,a5], [b1,b2,b3,b4,b5], [c1,c2,c3,c4] ..] # transpose the batch into # tgt_cws: [[a1,b1,c1,..], [a2,b2,c2,..], .. [a5,b5,</S>]] # masks: [1,1,1,..], [1,1,1,..], ...[1,1,0,..]] tgt_cws = [] masks = [] maxLen = max([len(l) for l in tgt_batch]) for i in range(maxLen): tgt_cws.append([]) masks.append([]) for sentence in tgt_batch: for j in range(maxLen): if j > len(sentence) - 1: tgt_cws[j].append('</S>') masks[j].append(0) else: tgt_cws[j].append(sentence[j]) masks[j].append(1) c_t = dy.vecInput(self.hidden_size * 2) start = dy.concatenate( [dy.lookup(self.tgt_lookup, self.tgt_token_to_id['<S>']), c_t]) dec_state = self.dec_builder.initial_state().add_input(start) for (cws, nws, mask) in zip(tgt_cws, tgt_cws[1:], masks): h_e = dec_state.output() _, c_t = self.__attention_mlp(h_fs_matrix, h_e, F) # Get the embedding for the current target word embed_t = dy.lookup_batch( self.tgt_lookup, [self.tgt_token_to_id.get(cw, 0) for cw in cws]) # Create input vector to the decoder x_t = dy.concatenate([embed_t, c_t]) dec_state = dec_state.add_input(x_t) y_star = dy.affine_transform([b_y, W_y, dec_state.output()]) loss = dy.pickneglogsoftmax_batch( y_star, [self.tgt_token_to_id.get(nw, 0) for nw in nws]) mask_exp = dy.reshape(dy.inputVector(mask), (1, ), len(mask)) loss = loss * mask_exp losses.append(loss) return dy.sum_batches(dy.esum(losses)), num_words